Intake-adaptable gas generator

ABSTRACT

A system includes a generator using a fluid mixture obtained via a generator inlet, a compressor having a compressor inlet that is connected to a generator outlet by a first set of conduits, a second set of conduits connected to the compressor outlet and the generator inlet, and a sensor in communication with the second set of conduits, where a portion of the fluid mixture includes gas from a gas emission source, and where exhaust fluid of the generator is provided to the compressor. A process includes obtaining a target fluid property and a fluid measurement using the sensor and modifying a parameter of a fluid control device to modify a first flow rate of the flow of the exhaust fluid through the second set of conduits relative to a second flow rate of the flow of the gas provided by gas emission source through the first set of conduits.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is continuation-in-part of U.S. application Ser.No. 17/675,427, filed Feb. 18, 2022, titled INTAKE-ADAPTABLE GASGENERATOR, which is a continuation of U.S. application Ser. No.17/360,097, filed Jun. 28, 2021, titled INTAKE-ADAPTABLE GAS GENERATOR,now U.S. Pat. No. 11,274,662, which claims priority to provisionalapplication 63/044,880 filed Jun. 26, 2020, titled INTAKE-ADAPTABLEGAS-POWERED GENERATOR. The entire contents of the aforementioned patentfilings are hereby incorporated by reference for all purposes.

BACKGROUND 1. Background

Hydrocarbon extraction from hydrocarbon wells often results in theproduction of volatile, combustible gases. In many cases, these gasesare infeasible to transport or otherwise process due to the low volumeor the lack of homogeneity in the gas mixture itself. Various extractionsites may include flaring systems designed to burn these gases in orderto prevent them from escaping into the atmosphere.

SUMMARY

The following is a non-exhaustive listing of some aspects of the presenttechniques. These and other aspects are described in the followingdisclosure.

Some embodiments may use a system including sensors, valves, pipes,compressors, and other fluid-measuring or fluid-handling equipment topower a gas generator using gas produced from a hydrocarbon well orobtained from a gas emission source due to an outgassing phenomenon.Some embodiments may inject the gas into a set of tanks that provide apositive pressure atmosphere that will divert gas from a vapordestruction system into a compression system when a set of gas criteriais satisfied. Some embodiments may further use the produced gas or gascombustion byproducts for reinjection into a well site, a gas emissionsite, or dry ice production.

Some aspects include a system includes a gas generator to generateelectrical energy using a fluid mixture obtained via a generator inletof the gas generator, wherein a portion of the fluid mixture comprisesgas provided by a gas emission source. The system may include acompressor, wherein a compressor inlet of the compressor is attached toa generator outlet of the gas generator by a first set of conduits, andwherein exhaust fluid of the gas generator is provided to the compressorvia the first set of conduits. The system may include a second set ofconduits connected to a compressor outlet of the compressor and thegenerator inlet. The system may include a sensor in communication withthe second set of conduits, wherein the sensor measures fluid propertiesof fluids flowing through a portion of the second set of conduits.

Some aspects include a process, the process including obtaining, with acomputer system, a target fluid property of a fluid mixture entering agenerator inlet. The process may include obtaining a fluid measurementof the fluid mixture using a sensor. The process may include determiningwhether the fluid measurement satisfies a criterion based on the targetfluid property. The process may include, in response to a determinationthat the target fluid property satisfies the criterion, modifying anoperational parameter of a set of fluid control devices to increase afirst flow rate relative to a second flow rate, wherein the first flowrate is a measurement of the flow of exhaust fluid through a first setof conduits, and wherein the second flow rate is a measurement of theflow of the gas provided by a gas emission source through a first set ofconduits.

Some aspects include a tangible, non-transitory, machine-readable mediumstoring instructions that when executed by a data processing apparatuscause the data processing apparatus to perform operations including theabove-mentioned process.

Some aspects include a system, including: one or more processors; andmemory storing instructions that when executed by the processors causethe processors to effectuate operations of the above-mentioned process.

BRIEF DESCRIPTION OF THE DRAWINGS

The above-mentioned aspects and other aspects of the present techniqueswill be better understood when the present application is read in viewof the following figures in which like numbers indicate similar oridentical elements:

FIG. 1 is a schematic diagram of a production system having anintake-adaptable gas generator system to generate electricity fromgaseous fluids using the present techniques, in accordance with someembodiments.

FIG. 2 is a schematic diagram of a portion of a gas extraction system ofan intake-adaptable gas generator system, in accordance with someembodiments.

FIG. 3 is a schematic diagram of a set of fluid tanks and a compressor,in accordance with some embodiments.

FIG. 4 is a schematic diagram of a gas generator with an integratedwater collection system, in accordance with some embodiments.

FIG. 5 is a schematic diagram of a gas generator with an integratedcarbon dioxide production system, in accordance with some embodiments.

FIG. 6 is a flowchart of operations to satisfy a set of criteria basedon a target value of an intake-adaptable gas generator system, inaccordance with some embodiments.

FIG. 7 shows an example of a computing device by which the presenttechniques may be implemented, in accordance with some embodiments.

While the present techniques are susceptible to various modificationsand alternative forms, specific embodiments thereof are shown by way ofexample in the drawings and will herein be described in detail. Thedrawings may not be to scale. It should be understood, however, that thedrawings and detailed description thereto are not intended to limit thepresent techniques to the particular form disclosed, but to thecontrary, the intention is to cover all modifications, equivalents, andalternatives falling within the spirit and scope of the presenttechniques as defined by the appended claims.

DETAILED DESCRIPTION OF CERTAIN EMBODIMENTS

To mitigate the problems described herein, the inventors had to bothinvent solutions and, in some cases just as importantly, recognizeproblems overlooked (or not yet foreseen) by others in the field ofpower generation. Indeed, the inventors wish to emphasize the difficultyof recognizing those problems that are nascent and will become much moreapparent in the future should trends in industry continue as theinventors expect. Further, because multiple problems are addressed, itshould be understood that some embodiments are problem-specific, and notall embodiments address every problem with traditional systems describedherein or provide every benefit described herein. That said,improvements that solve various permutations of these problems aredescribed below.

Gas emission sources such as, for example, hydrocarbon well systemsoften produce excess combustible gases at the site of a subsurfaceresource extraction operation. In many cases, these gases may not beviable for processing and transport off-site due to being ofinsufficient quantity or due to the lack of available infrastructure. Inaddition to gas obtained directly from a well or other gas emissionsource, a significant amount of gas escapes from produced liquids viaoutgassing through changes in liquid level fluctuations, increases ordecreases in internal tank pressure, or the like. Furthermore,fluid-handling operations at a well site, a gas emission site, or afluid processing site may introduce atmospheric oxygen into a fluidmixture, which may cause equipment corrosion or require the use ofoxygen removal equipment. Other gas emission sources include gasesreleased from decaying products in landfills or from decaying waste inanaerobic digesters included in wastewater treatment facilities.

Some systems may resolve this issue by treating these combustible gasesas a waste gas and burning (e.g., “flaring”) these gases on the site ofthe resource extraction operation (“on-site”). However, gas flaring maybe considered harmful or impractical in various environments. Moreover,such gases are energy-rich and may be harnessed to augment or replaceother energy supplies for on-site operations. However, theunpredictability of gas flow from a subsurface environment or fluidstorage tank (“fluid tank”) filled with fluids from a subsurfaceenvironment can make conventional generators inappropriate for on-sitepower generation due to the possibility of generator damage orunreliable power generation.

Some embodiments may include an intake-adaptable gas generator system tosupply power to an on-site well system or other gas emission system. Theintake-adaptable gas generator system may generate electricity fromwaste gas produced by a gas emission source and adapt source operationsto satisfy flow rate or concentration variation in gases produced by agas emission source. The intake-adaptable gas generator system mayinclude a computing device or set of computing devices to modify a fluidcontrol system of the intake-adaptable gas generator system based on aset of electrical measurements and fluid measurements. Some embodimentsmay obtain the set of electrical measurements from sensors measuring theactivity of electrical components of the on-site well system, on-sitegas emission system, or connected to the on-site well system or gasemission system. Some embodiments may obtain the set of fluidmeasurements from sensors measuring fluid properties, such as flow rate,pressure, temperature, composition, viscosity, or the like.

Some embodiments may perform operations to determine operationalparameters of electrical components or fluid control devices based onpredicted fluid flow rates or other fluid-related values or targetvalues. Some embodiments may execute a target operating mode, where thetarget operating mode may include a quantitative value such as thetarget value, where the target value may include a set point for a fluidproperty or a target operational parameter of a device. Some embodimentsmay predict a fluid intake value (e.g., a volume to be acquired in aduration of time, a gas flow rate over a time series, or the like) basedon the fluid measurements. Some embodiments may then determine a set ofparameters for satisfying a target operating mode (e.g., by meeting aset point for a measurement or being within a threshold range of the setpoint) based on the predicted fluid intake values and electricalmeasurements. Some embodiments may then modify operations of theintake-adaptable gas generator system, where such modifications mayinclude modifying a gas flow rate for a gas generator, a storagepressure for a fluid tank, or a load parameter for a compressor.Modifying operations of the intake-adaptable gas generator system mayinclude injecting flare gas or other waste gas into a set of fluidtanks, such as scrubber tanks, where the fluid tanks may provide apositive pressure atmosphere. The flare gas that is directed to a vapordestruction system may be diverted to a compression system when a set oftolerance criteria is met, where waste gases from various types ofoperations may be blended or otherwise combined. Some embodiments mayblend produced waste gas, outgassed gases, other gases obtained fromfluid tank vapors, or the like.

By using one or more operations or systems described in this disclosure,some embodiments may provide a method of efficiently using fluids from awell or other gas emission system for power generation. Such operationsmay reduce the amount of excess fluids (e.g., methane gas, ethane gas,alcohol gases or combinations of gases) being non-productively burned orreleased into the atmosphere. Furthermore, by providing electrical powerto a well production system, a landfill system, a wastewater treatmentsystem, or using a gas generator, some embodiments may reduce the amountof excess gas dissolved in a liquid or otherwise stored in a fluid tankused to transport liquid hydrocarbons. In addition, by reducing excessgas, some embodiments may increase operational efficiency and reducecorrosion in on-site or off-site equipment.

It should be noted that some items, such as a compressor or a gasgenerator, may be described as being connected by a set of conduits,such as a set of pipes, a set of open channels, a combination of pipesor open channels, or the like. As used in this disclosure, a first itemmay be connected to a second item via a set of conduits if a fluid maytravel from the first item to the second item within the set ofconduits, where different conduits of the set of conduits may beseparated by tanks, fluid control devices, or other objects. Forexample, a generator may be connected to a compressor by a pair of pipesif the generator is connected to a fluid tank via a first pipe of thepair of pipes, and the fluid tank is connected to the compressor by asecond pipe of the pair of pipes.

FIG. 1 is a schematic diagram of a production system having anintake-adaptable gas generator system to generate electricity fromgaseous fluids using the present techniques, in accordance with someembodiments. The gas generator system 100 may receive fluids via theinput pipe 102, which is attached to the hydrocarbon well 105 andprovides gas produced by the hydrocarbon well 105. While a hydrocarbonwell 105 is illustrated, reference number 105 may include any gasemission source that emits combustible gas such as, but not limited to,a landfill, anaerobic digesters included in wastewater treatmentfacilities or other gas emission sources in a wastewater treatmentfacility or other gas emission source that would be apparent to one ofskill in the art in possession of the present disclosure. Additionally,or alternatively, the gas generator system 100 may include a set offluid tanks 104 used to store fluids. Fluids from the input pipe 102 orthe set of fluid tanks 104 may be provided to a vapor sink 106, wherethe vapor sink 106 may include a flare stack or other gas emissionreleaser to burn or otherwise process vapors in a fluid. In someembodiments, fluid flow to the vapor sink 106 may be controlled throughactuation of a valve 113. In some embodiments, fluids in the input pipe102 may be redirected by a valve 114 into a vapor recovery compressor120.

In some embodiments, fluids from the set of fluid tanks 104 may beredirected to the vapor recovery compressor 120 by manipulating a valve108 to permit fluid to flow through a pipe 110. In some embodiments,fluids from the vapor recovery compressor 120 may be sent to a set offluid tanks 130. As further discussed, additional liquid phasecombustible materials or other materials may be isolated by the set offluid tanks 130. Additionally, some embodiments may transport theadditional liquid phase combustible materials through a valve 134 andinto the liquid return pipe 128. A fluid mixture comprising gas-phasefluids from the set of fluid tanks 130 may be transported to a gasgenerator 140 via a generator inlet pipe 132, where the fluid mixture isused by the gas generator 140 to generate electrical energy. As shown bythe gas generator system 100, the input pipe 102 may transport gas fromthe hydrocarbon well 105 or other gas emission source to the set offluid tanks 104. The set of fluid tanks 104 is connected to thegenerator inlet pipe 132 by other pipes or fluid control devices, suchas a vapor output pipe 122 or the vapor recovery compressor 120.Furthermore, while not shown in FIG. 1 , some embodiments may provide adirect connection between a pipe transporting gas from the hydrocarbonwell 105 or other gas emission source to the gas generator 140.

In some embodiments, the vapor recovery compressor 120 may sendhydrocarbon vapors or other materials in the gas phase through the vaporoutput pipe 122. Additionally, or alternatively, the vapor recoverycompressor 120 may output liquid phase hydrocarbons or other fluids inthe liquid phase through a valve 124 into a liquid return pipe 128.Furthermore, in some embodiments, the fluid in the liquid return pipe128 may be mixed with gas from the hydrocarbon well 105 or other gasemission source. Furthermore, as described elsewhere in this disclosure,the vapor recovery compressor 120 may receive exhaust fluid from the gasgenerator 140 as an input fluid, causing the fluid flowing through acompressor outlet 121 of the vapor recovery compressor 120 to be arecycled fluid mixture. As used in this disclosure, a recycled fluidmixture may include any fluid mixture that includes an exhaust fluid ofa gas generator.

In some embodiments, operations of the gas generator 140 or othercomponents of the gas generator system 100 may include obtaining sensormeasurements and modifying component configurations based on the sensormeasurements. Such sensor measurements may include fluid flow ratemeasurements obtained by flow meters, chemical sensors to detect thepresence of compounds or concentration of compounds, pressure differencemeasurements obtained from differential pressure sensors positioned atdifferent sides of a valve. For example, pressure sensors may be used toobtain a pressure difference across the valve 114 by measuring thepressure of fluids in the input pipe 102 and fluids in a fluid pipe 112.

As discussed further below, operations of the vapor recovery compressor120 may be modified to satisfy a criterion based on a target value. Thecriterion may include a criterion that a measured or computed value iswithin a defined range of the target value, that the measured orcomputed value is greater than the target value, or that the measured orcomputed value is less than the target value. For example, someembodiments modify an operation of a fluid control device such as thevalve 124 or the vapor recovery compressor 120 to satisfy a criterionthat a power generation of a gas generator 140 is within a range (e.g.,within 5%) of a target power generation value. Alternatively, someembodiments may modify an operation of a fluid control device inresponse to a determination that a gas consumption rate is less than atarget gas consumption value.

Operations of the gas generator 140 may be controlled by an on-boardcomputing device attached to the gas generator 140 may be remotelycontrolled by another computing device. For example, operations of thegas generator 140 may be controlled by modifying a parameter of thebidirectional inverter 150. In some embodiments, the gas generator 140may consume fluid from the generator inlet pipe 132 to generateelectricity that is transported through the wiring 146 and convertedinto direct current (DC) power via the bidirectional inverter 150, wherethe bidirectional inverter 150 may be used to account for predictedpower requirement changes. For example, some embodiments may use thebidirectional inverter 150 to increase power generation by the gasgenerator 140 during a periodic increase in the power requirement of anoscillating pump jack. Additionally, some embodiments may transportfluid such as liquid phase fluid to be liquid return pipe 128 via thevalve 144.

Some embodiments may include a second inverter 160 that is wired to thebidirectional inverter 150 via the wire 152, where the second inverter160 may be used to generate a three-phase alternating current (AC)through the first wire 161. Some embodiments may also include ameasurement of a current on-site electrical load of the on-siteelectrical load sensor 163. Some embodiments may then communicate thecurrent from the second inverter 160 and the current measured by theon-site electrical load sensor 163 to an electrical service maincontroller 164. In some embodiments, the electrical service maincontroller 164 may receive measurements from an external electrical gridindicating an amount of power being provided by the external electricalgrid (e.g., utility grid). In some embodiments, the electrical servicemain controller 164 may be in electrical communication with othercomponents of an on-site set of components 162, which may include a pumpjack, pressurizing equipment, workstation, hoisting system, or the like.As discussed further below, some embodiments may determine a targetparameter, such as a target wattage, target electrical waveform, targetcurrent, target voltage, target gas consumption value, target gasstorage value, or the like. Some embodiments may then modify operationsone or more components of the gas generator system 100 to meet thetarget parameter.

As used in this disclosure, a measurement, such as an electricalmeasurement or fluid measurement, may include a direct measurementobtained from a sensor. Alternatively, or in addition, a measurement mayinclude a measure based on a plurality of other measurements. Forexample, a fluid measurement may include a maximum value of a pluralityof fluid measurements or a minimum value of a plurality of fluidmeasurements. Furthermore, a measurement may include a statisticalmeasurement, such as a measure of centralized tendency (e.g., a meanaverage, a median, a mode, or the like) or a measure of dispersion(e.g., a variance, a standard deviation, or the like). Furthermore, asused in this disclosure, a sensor in communication with a conduit, atank, another fluid vessel, a well, or other gas emission source maymeasure one or more properties of a fluid in the conduit, tank, or otherfluid vessel. For example, a first sensor that measures a fluidtemperature, fluid pressure, or fluid flow rate through a pipe is incommunication with the pipe. In some embodiments, a sensor may beattached to a conduit, tank, well, or other gas emission source tomeasure a fluid in the conduit, tank, well, or other gas emissionsource. For example, a resistivity sensor may be physically attached toan inner wall of a pipe. Alternatively, or in addition, a sensor may bephysically detached from a conduit, tank, or well while still being incommunication with the conduit, tank, well, or other gas emissionsource. For example, an infrared temperature sensor may be used toobtain a temperature of a fluid flowing through a pipe without beingphysically attached to the pipe.

FIG. 2 is a schematic diagram of a portion of a gas extraction system ofan intake-adaptable gas generator system, in accordance with someembodiments. An intake-adaptable gas generator system 200 may include agas generator 256 to provide electrical energy to a set of componentselectrically connected to the gas generator. Such components may includea computing system(s) 298, a subset of computing devices of a computingsystem pumping devices or their controllers, workstations, digitaldisplays, mobile devices, electric charging stations, or otherelectricity-consuming devices. The intake-adaptable gas generator system200 may include a fluid inlet pipe 202 from a fluid tank 203 or a fluidinlet pipe 204 from a hydrocarbon well 205 or other gas emission source.The hydrocarbon well 205 or other gas emission source may providevarious fluids, such as water, oil, gases, or the like to a fluid tank203 via a pipe 291. In addition, an exhaust fluid, such as a gas mixtureof carbon dioxide and water vapor, of the gas generator 256 may bere-directed to a compressor 220 via the exhaust fluid pipe 258. Theexhaust fluid of the gas generator 256 may be shunted through thegenerator outlet 257 through the exhaust fluid pipe 258, where the flowrate of the exhaust fluid mixture may be controlled by a valve 261.Furthermore, while not shown in FIG. 2 , some embodiments may connect agenerator outlet with other elements of the intake-adaptable gasgenerator system 200. Furthermore, in some embodiments, the fluid tank203 may include hydrocarbon fluids provided from other sources. In someembodiments, the gas generator 256 may be provided with additionalhydrocarbon fluids to use as fuel for the generation of electricalenergy. For example, the gas generator 256 may be provided with apropane tank that may be used concurrently or separately from gasprovided by the hydrocarbon well 205 or other gas emission source.

In some embodiments, the computing system(s) 298 may include a wirelessnetwork interface to receive and interpret wireless signals, where awireless signal may include WiFi signals, cellular network signals,long-range radio signals, or the like. For example, the computingsystem(s) 298 may include a long range radio module to receive radiocommunication. One or more processors of the computing system(s) 298 maythen determine a set of values using the wireless signals, where the setof values may include target values, operational parameters, programinstructions, or the like. Some embodiments may then use the computingsystem(s) 298 to perform one or more operations described in thisdisclosure using components of the intake-adaptable gas generator system200.

The fluid inlet pipe 202 may include fluid from a well, a fluid tank,another type of fluid vessel, other gas emission source, or the like.For example, the fluid in the fluid inlet pipe 202 may include fluidstransported from the fluid pipe 110 or the fluid pipe 112. Fluids fromthe fluid in the fluid inlet pipe 202 may enter the suction scrubbertank 210, which may include a low liquid sensor 211, high liquid sensor212, or ultrahigh liquid sensor 213. While described a scrubber, itshould be understood that the scrubber tanks 210, 230, or 240 may bereplaced with other types of fluid tanks. Fluids may be separated at thesuction scrubber tank 210 into a gas phase fluid and a liquid phasefluid. In some embodiments, the gas phase fluid may be transported intothe compressor 220. In some embodiments, the gas phase fluid may bemixed with exhaust fluid from the gas generator 256 to form a recycledfluid mixture. Additionally, the liquid phase fluid may be sent into aliquid return pipe 223 by sending instructions to a controller operatinga valve 215 that connects the liquid return pipe 223 to the suctionscrubber tank 210. A differential pressure sensor 216 may provide ameasurement of the pressure difference across the valve 215 or a measureof the fluid pressure(s) at either end of the valve 215. In someembodiments, a controller may actuate or otherwise modify the valve 215to allow fluid to flow into a fluid tank 203.

In some embodiments, measurements from the set of sensors 211-213 may beused to modify an operation of the intake-adaptable gas generator system200 or another component connected to the gas generator 256. Forexample, some embodiments may determine that a liquid level hassatisfied a threshold liquid height based on measurements from the lowliquid sensor 211 and, in response, open the valve 215 to a partiallyopened state. Additionally, some embodiments may determine that a liquidlevel is satisfied a second threshold liquid height based onmeasurements from the high liquid sensor 212 and, in response, open thevalve 215 to a fully open state. In some embodiments, a tank purge pipe282 may be used to connect fluids flowing from the suction scrubber tank210 back into fluids flowing into the suction scrubber tank 210 or toanother pipe.

In some embodiments, fluid sent to the compressor 220 may be compressedand transported to a discharge scrubber tank 230, where the fluid may beseparated by the compressor 220 into a gas phase fluid and a liquidphase fluid. By using the compressor 220, some embodiments may increasethe homogeneity or purity of an output gas phase fluid. Once sent to thedischarge scrubber tank 230, the liquid phase fluid may be transportedinto the liquid return pipe 223 via the valve 235. Similar to the above,the liquid volume sensors 231-233 may be used to determine anoperational parameter of a component of the intake-adaptable gasgenerator system 200 or another component connected to an on-site, gasgenerator. Some embodiments may include a differential pressure sensor236 to provide a measure of the pressure difference across the valve 235or a measure of the fluid pressure(s) at either end of the valve 235. Insome embodiments, a controller may actuate or otherwise modify the valve235 to allow fluid to flow into a fluid tank 203 via a fluid outlet 237connected to the valve 235. In some embodiments, the fluid tank 203 mayalso include a tank pressure release valve 293 or tank hatch pressurerelief element 294 to mitigate pressurization risks.

In some embodiments, the discharge scrubber tank 230 may be connected toa scrubber tank 240 via the tank connection pipe 247, where the scrubbertank 240 may serve as an additional scrubber. In some embodiments, thetank connection pipe 247 may be positioned between the dischargescrubber tank 230 and the scrubber tank 240, where the tank connectionpipe 247 is at an angle with respect to a horizontal line between thedischarge scrubber tank 230 and the scrubber tank 240. In someembodiments, the tank connection pipe 247 may be angled to reducefurther the amount of fluid stored in a liquid phase in the scrubbertank 240 by allowing condensates to flow from the scrubber tank 240 backto the discharge scrubber tank 230. In some embodiments, liquid phasefluids of the scrubber tank 240 may be transported into the liquidreturn pipe 223 via a valve 245. Similar to the above, the liquid volumesensors 241-243 may be used to determine an operational parameter of acomponent of the intake-adaptable gas generator system 200 or anothercomponent connected to the gas generator 256. Some embodiments mayinclude a differential pressure sensor 246 to provide a measurement ofthe pressure difference across the valve 245 or a measure of the fluidpressure(s) at either end of the valve 245. In some embodiments, acontroller may actuate or otherwise modify the valve 245 to allow fluidto flow into a fluid tank 203 based on an operational parameter of thevalve 245. For example, a controller may actuate the valve 245 to being50% open based on an operational parameter of the valve 245 being equalto 50%. Furthermore, a pump 225 may be used to pump liquid in the liquidreturn pipe 223 into the fluid tank 203, where the liquid in the liquidreturn pipe may include liquid from the tanks 210, 230, or 240.

In some embodiments, gas-phase fluid from the scrubber tank 240 may betransported to a gas generator via a pipe 255. In some embodiments, thepipe 255 may directly connect to a generator inlet 232 of the gasgenerator 256. As discussed elsewhere in this disclosure, someembodiments may modify operations of one or more components of theintake-adaptable gas generator system 200 based on a target value, suchas a measurable set point, a target operational parameter, or the like.For example, some embodiments may modify an operation of the gasgenerator 256 based on a target generator load, a target contribution tothe power consumed by components electrically connected to the gasgenerator 256, or the like.

In some embodiments, other sensors may be used to obtain a set ofmeasurements. The intake-adaptable gas generator system 200 may includea tank pressure sensor 271 to provide pressure measurements for thefluid tank 203 and a pipe pressure sensor 292 to obtain pressuremeasurements for fluid in the pipe 291. Differential pressure sensorsmay be used to provide a pressure difference between two differentpositions of the intake-adaptable gas generator system 200. For example,a differential pressure sensor 272 may be used to provide a differentialpressure measurement for a pipe 201, which may be used to transportfluid (e.g., hydrocarbon vapors) from the fluid tank 203. Similarly, aset of differential pressure sensors 274 may be used to provide adifferential pressure measurement for a pipe 273, which may be used totransport fluid (e.g., hydrocarbon vapors) from the hydrocarbon well 205or other gas emission source.

In some embodiments, a set of fluid measurements may include fluidcomposition measurements obtained by a set of sensors. For example, anoxygen sensor 221 may be positioned on the pipe 201 to obtain oxygenconcentrations measurement of fluid flowing from the fluid tank 203. Theoxygen concentration measurements may include relative concentrationmeasurements (e.g., such as percentage of atmospheric oxygenconcentration) or absolute concentration measurements (e.g., parts permillion). Similarly, the oxygen sensor 214 may provide oxygenconcentration measurements of the suction scrubber tank 210. Variousother oxygen sensors or other gas sensors (e.g., nitrogen, sulfur, orthe like) may be positioned at pipes, tanks, or other vessels of theintake-adaptable gas generator system 200, where having oxygenconcentration that are less than a lower threshold or greater than ahigh threshold may cause the injection or removal of oxygen in a fluidmixture, respectively.

In some embodiments, the vapor removal unit 299 may include a gasflaring system, a waste containment system, or other gas emissionrelease system to remove combustible gases from an intake-adaptable gasgenerator system. Some embodiments may describe the vapor removal unit299 as a gas flare system, various other systems are possible. Forexample, some embodiments may use a subsurface injection system toinject vapor into an underground storage chamber.

In some embodiments, various valves may be actuated to modify pressures,flow rates, fluid recycle rates, or the like. A check valve 281 maycontrol an amount of fluid to be sent to the vapor removal unit 299 fromthe fluid tank 203 via the pipe 201 and may be used to prevent fluidfrom leaving the vapor removal unit 299 through the pipe 201. Similarly,a check valve 222 may control an amount of fluid to be sent from thehydrocarbon well 205 or other gas emission source to the vapor removalunit 299 via a pipe 273 and may be used to prevent fluid from leavingthe vapor removal unit 299 through the pipe 273. A pressure regulatorvalve 217 may be used in conjunction with a shut-off valve 218 tocontrol fluid flow from the fluid tank 203 to the suction scrubber tank210. Similarly, a pressure regulator valve 219 may be used to regulate apressure of fluid flowing from the hydrocarbon well 205 or other gasemission source to the suction scrubber tank 210. In some embodiments,some or all of the valves described above may be controllable to adjusta maximum allowable pressure of a tank or other fluid-holding componentof the intake-adaptable gas generator system 200. In some embodiments,one or more of the compressors or other pumps described above may bemodified to change a tank pressure, change a temperature, or change afluid flow rate (e.g., a gas flow rate into the gas generator 256).

FIG. 3 is a schematic diagram of a set of fluid tanks and a compressor,in accordance with some embodiments. In some embodiments, fluidsproduced by a gas well, a wastewater treat facility, or landfill may bepurified, filtered, or otherwise processed using a set of tanks andcompressors. The schematic diagram 300 includes a first fluid tank 310,a first compressor 320, a second fluid tank 330, and a third fluid tank340. Some embodiments may include an inlet pipe 302 that provides fluidsfrom a hydrocarbon well, other gas emission source, or a generator gasoutlet to the first fluid tank 310. The first compressor 320 may thencompress fluids from fluids flowing out of the first fluid tank 310 intothe compressor inlet 321, where the compressed fluids may then be sentto the second fluid tank 330. In some embodiments, measurements made bya set of sensors 311 may be used to modify a valve controlling a fluidflow rate into the first fluid tank 310, where the set of sensors 311may include one or more sensors usable to determine an amount of aliquid in a tank (e.g., by determining the height of a liquid in thetank). For example, the set of sensors 311 may include a low liquidsensor, a high liquid sensor, or a high-high liquid sensor, each ofwhich may be used to indicate a relative or absolute height of a liquidin the tank. In some embodiments, the first fluid tank 310 may be usedas a suction scrubber tank to act as an initial vessel to receive fluidsfrom a gas emission source such as a hydrocarbon well, a landfill, awastewater treatment facility, or exhaust fluid from a gas engine.

In some embodiments, fluid provided by the first compressor 320 may beprovided to the second fluid tank 330, where the second fluid tank 330may be used as a discharge scrubber to process fluids sent from thefirst compressor 320. Furthermore, the second fluid tank 330 may beconnected to a third fluid tank 340 via a pipe 346, where the pipe 346is connected to the second fluid tank 330 at an attachment point 332,and where the pipe 346 is connected to the third fluid tank 340 at anattachment point 342. In some embodiments, the attachment point 342 maybe at a greater height compared to the attachment point 332, where theheight difference may permit condensate to escape from the third fluidtank 340 back to the second fluid tank 330.

In some embodiments, sensor measurements provided by the set of sensors311, the set of sensors 331, or the set of sensors 341 may providevarious measures of fluid properties or fluid volumes of fluids in thefluid tanks 310, 330, or 340, respectively. Based on one or more sensormeasurements, some embodiments may actuate one or more valves connectedto one or more of the fluid tanks 310, 330 or 340. In some embodiments,the set of sensors 311, 331, or 341 may indicate that a threshold liquidvolume has been reached by the respective fluid tank of the fluid tanks310, 330, or 340. For example, the set of sensors 331 may include ahigh-high liquid sensor that provides a measurement that indicateswhether a liquid volume of the second fluid tank 330 satisfies avalve-triggering threshold. In response to a determination that themeasurement indicates that the liquid volume of the second fluid tank330 satisfies the valve-triggering threshold, the valve 335 may beactuated. By actuating the valve 335, some embodiments may empty liquidsstored in the second fluid tank 330 via the fluid outlet 334, where thefluid outlet is lower in height than the attachment point 332.Similarly, the valves 315 and the valve 345 may be used to empty liquidsfrom the first fluid tank 310 via the fluid outlet 314 and the thirdfluid tank 340 via the fluid outlet 334, respectively. Some embodimentsmay empty liquids from the first fluid tank 310, second fluid tank 330,or third fluid tank 340 into a liquid return pipe 323, where a pump 325may transport the liquid fluid into a liquid fluid tank, such as thefluid tank 203. Some embodiments may then collect fluid (e.g.,hydrocarbon-rich gas) from the third fluid tank 340 for the purposes ofcombustion in a gas generator. As described elsewhere, some embodimentsmay mix this gas with other fluids such as atmospheric air, compressedexhaust fluid from a gas generator, or the like.

FIG. 4 is a schematic diagram of a gas generator with an integratedwater collection system, in accordance with some embodiments. FIG. 4 isa schematic diagram of a gas generator with an integrated watercollection system. The schematic diagram 400 depicts a gas generator 401receiving a first input gas via a generator inlet 402, where the datareceived via the generator inlet 402 may include a fluid mixture of gasprovided by a hydrocarbon well or other gas emission source andatmospheric air. The gas generator 401 may also receive a fuel intakevia a pipe 471 that connects to a generator inlet 472 of the gasgenerator 401.

As described elsewhere in this disclosure, some embodiments may controloperations of the gas generator 401 by increasing a power generationrate, turning on the gas generator 401, stopping the gas generator 401,or the like. Exhaust gas from the gas generator 401 may leave the gasgenerator 401 via the generator outlet 404, where the generator outlet404 may be connected to a pipe 481. In some embodiments, fluidproperties of fluids flowing from the generator outlet 404 may bemeasured by a temperature sensor 405, a nitrogen oxides sensor 406, or apressure sensor 407. It should be understood that oxides may include anytype of compound comprising at least one oxygen molecule. For example,nitrogen oxides may include nitrogen monoxide, nitrogen dioxide, ornitrogen trioxide. In some embodiments, a differential pressure sensor407 may be used to obtain a differential pressure measurement. Someembodiments may determine whether a valve 403 should be actuated topermit fluid flowing from the generator outlet 404 to an atmosphere or avapor destruction unit via a pipe 409 based on the differential pressuremeasurement. For example, a temperature measurement made by thetemperature sensor 405 may exceed a temperature threshold, a set ofnitrogen dioxide measurements made by the nitrogen oxides sensor 406 mayexceed a nitrogen oxides threshold, or a pressure difference measured bythe pressure sensors 407 and 408 may exceed a pressure threshold. Inresponse, some embodiments may actuate the valve 403 to permit fluid toflow into a vapor destruction unit via a pipe 409.

The pipe 481 may connect to an evaporator 410, where the evaporator 410may be used to evaporate water in fluid provided by the pipe 481. Insome embodiments, the evaporator 410 may remove water from fluidprovided by the gas generator 401, where water vapor may be released viaa first evaporator outlet 415. Alternatively, or in addition, fluidsfrom the evaporator 410 may be pumped or otherwise sent to a fluid tank411 via a pipe 413, where the fluid tank 411 may be used to cool orconcentrate fluid provided by the evaporator 410. Furthermore, it shouldbe understood that while some embodiments may obtain fluid from ahydrocarbon well, other wells (e.g., water wells) or wastewatertreatment fluids may be used.

In some embodiments, the fluid may be filtered by a filter of theevaporator 410 or the fluid tank 411 to remove solid matter from theevaporator 410 or the fluid tank 411. In some embodiments, the removedsolid matter may include various types of elements such as a transitionmetal such as cobalt or scandium, an alkali metal such as lithium, orother elements or compounds. The fluid tank 411 may provide the filteredfluid to the fluid tank 424. In some embodiments, filtered fluids fromthe fluid tank 424 may then be sent via a feed pipe 412 back to theevaporator 410 for additional processing or for cooling purposes. Forexample, the water flowing through the feed pipe 412 may be at a lessertemperature than the exhaust fluid flowing through the evaporator 410 asa result of convection or conduction. Some embodiments may increase awater flow through a set of pipes or other set of conduits running inthe evaporator 410 to increase gas condensation or perform other coolingactivity. For example, in response to a determination that an exhausttemperature is greater than a temperature threshold, some embodimentsmay increase a water flow through a set of pipes of the evaporator 410.Furthermore, in some embodiments, the evaporator 410 may include a gascondenser. As shown by the schematic diagram 400, exhaust fluid may becondensed by the evaporator 410 and transported through the pipe 421,where a temperature sensor 416 or a differential pressure sensor 417 maybe used to provide fluid properties of any fluids flowing in the pipe421 or in an exhaust pipe 419 that is connected to the pipe 421 via anexhaust bypass valve 420. Some embodiments may actuate or otherwisemanipulate the exhaust bypass valve 422 to permit exhaust fluid to bevented via the exhaust pipe 419.

In some embodiments, the cooled exhaust fluid provided by the evaporator410 may be sent to a heat exchanger 430, where the heat exchanger 430may be used to further reduce the temperature of the cooled exhaustfluid. In some embodiments, external cooling fluids such as water from alocal water source may be used to cool exhaust fluid flowing through theheat exchanger 430. Alternatively, or in addition, water from the set offluid tanks 424 or other liquids that are at a lesser temperature thanthe exhaust fluid flowing through the heat exchanger 430 may be used tochill exhaust fluid flowing through the heat exchanger 430. Furthermore,some embodiments may increase a water flow or flow rate of otherchilling fluid flowing through the heat exchanger 430 in response to adetermination that exhaust gas temperature is greater than a temperaturethreshold. Exhaust gas or other fluid from the heat exchanger 430 maythen be sent to a compressor 440, where a suction tank 441 may be usedto draw fluids from the heat exchanger 430 and send the fluids to thecompressor inlet 491 of the compressor 440.

In some embodiments, gas may flow through a fuel gas supply pipe 445 tosend the gas into the compressor 440, where a pressure difference may bemeasured by a differential pressure sensor 442, and where a flow rate offluid through the fuel gas supply pipe 445 is controlled by a valve 444.In some embodiments, the gas flowing through the fuel gas supply pipe445 and the exhaust fluid sent from the heat exchanger 430 may becombined in the compressor 440, where the gas mixture may be sent outfrom a compressor outlet 448 to a set of fluid tanks 450. As describedelsewhere in this disclosure, gas from the set of fluid tanks 450 maythen be sent back to a gas generator for combustion and energygeneration by the gas generator 401.

In some embodiments, the gas mixture sent out of the compressor 440 viathe compressor outlet 448 may be measured by a sensor usable fordetecting a target fluid property, such as an energy density sensor 446.For example, some embodiments may measure an amount of energy in Britishthermal units (BTU) of a volume of gas, such as a cubic foot. Variousother units of energy density may be used, such as joules per cubiccentimeter, kilowatt-hours per cubic meter, BTUs per cubic inch, or thelike. Some embodiments may then modify an operation of the compressor440 or one or more valves such as a valve 431 or a valve 432 to modify aproportion of gases of the gas mixture sent through the compressoroutlet 448. For example, in some embodiments, the energy density sensor446 may be a gas BTU meter, where the gas BTU meter may provide ameasurement of gas BTU per cubic foot. Some embodiments may then comparethe gas BTU meter measurement with a first threshold representing aminimum gas energy density and modify a compressor operational parameteror a valve parameter to increase the ratio of gas flowing from the fuelgas supply pipe 445 in the gas mixture relative to the exhaust fluidflowing from the heat exchanger 430. Alternatively, or in addition, someembodiments may determine whether a gas BTU meter measurement satisfiesa second threshold representing a maximum gas energy density. Inresponse to determining that the gas BTU meter measurement satisfies thesecond threshold, some embodiments may modify a compressor operationalparameter or a valve parameter to decrease the ratio of gas flowing fromthe fuel gas supply pipe 445 in the gas mixture relative to the exhaustfluid flowing from the heat exchanger 430. By mixing exhaust fluid withdata provided by the fuel gas supply pipe 445, some embodiments mayaccount for cases where produced gas has a greater energy density than asafe energy density range of a gas generator.

FIG. 5 is a schematic diagram of a gas generator with an integratedcarbon dioxide production system, in accordance with some embodiments.The schematic diagram 500 depicts a gas generator 501 receiving a firstinput gas via a generator inlet 502, where the data received via thegenerator inlet 502 may include a fluid mixture of gas provided by a gasemission source and atmospheric air. The gas generator 501 may alsoreceive a fuel intake via a pipe 571 that connects to a generator inlet572 of the gas generator 501. While not shown in FIG. 5 , the generatorinlet 572 may receive a recycled fluid mixture provided by a compressor,as described elsewhere in this disclosure.

As described elsewhere in this disclosure, some embodiments may controloperations of the gas generator 501 by increasing a power generationrate, turning on the gas generator 501, stopping the gas generator 501,or the like. Exhaust gas from the gas generator 501 may leave the gasgenerator 501 via the generator outlet 504, where the generator outlet504 may be connected to a pipe 581. In some embodiments, fluidproperties of fluids flowing from the generator outlet 504 may bemeasured by a temperature sensor 505, a nitrogen oxides sensor 506, or adifferential pressure sensor 507. In some embodiments, a differentialpressure measurement made by the differential pressure sensor 507 may beused to determine whether a valve 503 should be actuated to permit fluidflowing from the generator outlet 504 to be exhausted to an atmosphereor a vapor destruction unit via a pipe 509.

In some embodiments, the pipe 581 may connect to an evaporator 510,where the evaporator 510 may be used to evaporate water in fluidprovided by the pipe 581. Similar to other embodiments described in thisdisclosure, the evaporator 510 may remove water from fluid provided bythe gas generator 501, where water vapor may be released via a firstevaporator outlet 515. Alternatively, or in addition, fluids from theevaporator 510 may be pumped or otherwise sent to a fluid tank 511 via apipe 513, where the fluid tank 511 may be used to cool or otherwiseconcentrate fluid provided by the evaporator 510.

In some embodiments, the fluid may be filtered by a filter of theevaporator 510 or the fluid tank 511 to remove solid matter. In someembodiments, the removed solid matter may be collected from theevaporator 510 or the fluid tank 511. The fluid tank 511 may providefluid to the fluid tank 524, where the fluid may include concentrateoverflow from the fluid tank 511. In some embodiments, fluids from thefluid tank 524 may then be sent via a pipe 512 back to the evaporator510 for additional processing or for cooling purposes. Furthermore, insome embodiments, the evaporator 510 may also include or instead be agas condenser. As shown by the schematic diagram 500, exhaust fluid maybe condensed by the evaporator 510 and transported through the pipe 521,where a temperature sensor 516 or a differential pressure sensor 517 maybe used to provide fluid properties of any fluids flowing in the pipe521 or in exhaust pipe 519 that is connected to the pipe 521 via anexhaust bypass valve 520. Some embodiments may actuate or otherwisemanipulate the exhaust bypass valve 520 permit exhaust fluid to bevented via the exhaust pipe 519.

In some embodiments, the cooled exhaust fluid provided by the evaporator510 may be sent to a heat exchanger 530, where the heat exchanger 530may be used to further reduce the temperature of the cooled exhaustfluid. In some embodiments, external cooling fluids such as water from alocal water source may be used to cool exhaust fluid flowing through theheat exchanger 530. Alternatively, or in addition, water or otherliquids from the set of fluid tanks 524 may be used to chill exhaustfluid flowing through the heat exchanger 530. Exhaust gas or other fluidfrom the heat exchanger 530 may then be sent to a compressor 540, wherea suction tank 541 may be used to draw fluids from the heat exchanger530.

In some embodiments, cooled exhaust fluid may be sent from the heatexchanger 530 to a carbon dioxide processing system 550, where thecarbon dioxide processing system 550 may extract carbon dioxide from theexhaust fluid. In some embodiments, the carbon dioxide processing system550 may include a gas pressurizer to pressurize the exhaust fluid toform liquid carbon dioxide. For example, the carbon dioxide processingsystem may use a gas pressurizer to pressurize a gas to a pressuregreater than 5000 kilopascals (e.g., 5600 kilopascals) to generateliquid carbon dioxide. Some embodiments may include filters to collectcarbon dioxide or filter out other gases. Some embodiments may transportthe liquid carbon dioxide to a carbon dioxide fluid tank 552 via a setof pipes 551, where a carbon dioxide blending valve 567 may be used tocontrol an amount of carbon dioxide that is redirected into an airintake for the gas generator 501, as described elsewhere in thisdisclosure. Some embodiments may then supply a solid carbon dioxideproduction system 554 with liquid carbon dioxide from the carbon dioxidefluid tank 552. The solid carbon dioxide (i.e., “dry ice”) may then betransported to a dry ice repository 555 for later removal.

In some embodiments, a gas source 560 may be used to provide a set ofgases such as oxygen gas, an inert gas (e.g., argon gas), or the like.The gas source 560 may include an oxygen generation plant, a noble gasfluid tank, or other sources of one or more gases. Some embodiments maycontrol an amount of oxygen gas or inert gas of a gas mixture providedby the gas source 560 using a set of valves such as an oxygen blendingvalve 561, an inert gas blending valve 568, or the carbon dioxideblending valve 567. Some embodiments may modify the concentration ofgases based on measurements made by a gas sensor 563, where the gassensor 563 may include an oxygen sensor, a carbon dioxide sensor, ahydrocarbon gas sensor, or the like. Some embodiments may control theproportion of gases of the gas mixture, where the gases may includefluids provided by the set of pipes 551 or fluids provided byatmospheric air flowing through the pipe 566. Some embodiments maycontrol the proportions of mixing or the flow rates by actuating one ormore of a valve 562 or a valve 565, where the valve 562 may control aflow rate of fluid flowing from the set of pipes 551 to the generatorinlet 502, and where the valve 565 may control a flow rate of fluidflowing from the pipe 566 to the generator in the 502.

Example Flowchart

FIG. 6 is a flowchart of operations to satisfy a set of criteria basedon a target value of an intake-adaptable gas generator system, inaccordance with some embodiments. In some embodiments, the process 600,like the other processes and functionality described herein, may beimplemented by an entity-tracking system that includes computer codestored on a tangible, non-transitory, machine-readable medium, such thatwhen instructions of the code are executed by one or more processors,the described functionality may be effectuated. Instructions may bedistributed on multiple physical instances of memory, e.g., in differentcomputing devices, or in a single device or a single physical instanceof memory, all consistent with use of the singular term “medium.” Insome embodiments, the operations may be executed in a different orderfrom that described. For example, while the process 600 is described asperforming the operations corresponding to block 620 before performingthe operations corresponding to block 630, some embodiments may performthe operations corresponding to block 630 before performing thosecorresponding to block 620. In some embodiments, operations may beexecuted multiple times per instance of the process's execution, someoperations may be omitted, additional operations may be added, someoperations may be executed concurrently and other operations may beexecuted serially, none of which is to suggest that any other featuredescribed herein is not also amenable to variation.

In some embodiments, the process 600 may include obtaining a targetvalue, as indicated by block 610. In some embodiments, the target valuemay be associated with a selected operating mode of the intake-adaptablegas generator system. For example, the target value may be associatedwith written descriptions such as “consume a maximum amount of producedgases,” “maximize power generation,” or “prevent power use of energyfrom external grid systems from reaching threshold value” in a storeddata table. The target value may be stored as an absolute value, arelative percentage of a pre-set constant, or the like. In someembodiments, an operating mode may be configured for the operations ofan intake-adaptable gas generator system. For example, some embodimentsmay modify operational parameters of one or more components of theintake-adaptable gas generator system to satisfy a set of criteria basedon a target value while keeping other parameters or measurements withina pre-set range.

Some embodiments may obtain a target value as a set point, such as a setpoint corresponding to a target power output. The target value may bestored as an absolute target power output, a relative percentage of apower output constant, or the like. For example, some embodiments mayexecute instructions causing a gas generator to produce 100% of apre-set constant power generation equal to 5 kilowatts. In someembodiments, the power generation rate may change over time, where thegoal of the power generation rate is to keep a total amount of powerbeing provided by an external electrical system (e.g., a utility gridsystem) below a threshold value. For example, a pump jack may oscillatebetween using 40 kilowatts (kW) to 5 kW in a pumping cycle. The targetvalue may then dynamically change to supplement energy use greater than10 kW such that the target power output is 0 kW for the duration whenthe pump jack is using between 5-10 kW, and such that the target poweroutput changes between 0 kW to 30 kW when the pump jack is between usingbetween 10 kW to 40 kW.

Some embodiments may be configured to an operating mode to satisfy atarget gas consumption amount, where a target value of the operatingmode may include a value indicating a consumption amount. For example,an operating mode of some embodiments may be configured to consume 100%of hydrocarbon gas being produced by a hydrocarbon well or other gasemission source, where the target parameter may be equal to 100% or beequal to a different amount of a gas being produced by the gas emissionsource. Such operating modes may be useful in environments that do notpermit gas flaring or other forms of gas destruction. Furthermore, insome embodiments, the target gas consumption amount may vary based onother factors, where a portion of gas produced by a gas emission sourcemay be diverted to a fluid tank or pipeline for transport away from ahydrocarbon production field. As described elsewhere in this disclosure,various operating parameters of fluid control devices or othercomponents of an intake-adaptable gas generator system may be actuatedor otherwise modified to satisfy a set of criteria based on a targetvalue. For example, some embodiments may satisfy a criterion based on atarget value by increasing an allowable storage pressure of a fluidtank, modifying a load of a compressor, actuating a valve to change anamount of a fluid mixture used to fuel the gas generator or change acomposition of the fluid mixture, or the like.

In some embodiments, the target value, instructions to use the targetvalue, or program code to perform one or more operations described inthis disclosure may be obtained from a remote computing device. Forexample, some embodiments may receive a wireless signal (e.g., acellular signal, a WiFi signal, a long-range radio signal, etc.) from acell tower via a wireless signal receiver. The wireless signal mayinclude a target value and a set of data associated with the targetvalue. Some embodiments may then use an on-site computing device, suchas a set of controllers, to perform one or more operations described inthis disclosure based on the target value.

In some embodiments, the process 600 may include obtaining a set ofelectrical measurements of an intake-adaptable gas generator system, asindicated by block 620. The set of electrical measurements may includeone or more types of electrical measurements, such as a currentmeasurement, voltage measurement (e.g., a root mean square voltage in analternating current), amperage measurement, or the like. Alternatively,or in addition, the set of electrical measurements may include othermeasures or properties of electrical power such as a positive ornegative power flow, an amount of active power being supplied, an amountof reactive power, an amount of apparent power, or the like. Someembodiments may include specific measurements indicating a total amountof power being acquired or provided by a generator or inverter on-siteelectrical components or electrical grid connected to theintake-adaptable gas generator system. For example, some embodiments mayinclude specific measurements of a total amount of power being acquiredfrom an electrical grid system or provided to an electrical grid system.In addition, some embodiments may use the amounts of power or energy todetermine a cost of the power being bought or sold via anenergy-to-price weighting factor or function. Furthermore, as describedelsewhere in this disclosure, some embodiments may provide measurementsof power or energy being provided or sold to a grid system.

Some embodiments may obtain measurements over a period of time orprocesses measurements to indicate changes in power consumption based onon-site operations. For example, some embodiments may obtainmeasurements indicating power oscillation reflecting the loading andunloading phases of a pump jack or other types of motorized oscillatingequipment. As described elsewhere in this disclosure, motorizedoscillating equipment may have a corresponding oscillating powerrequirement, where the oscillating power requirements may exceedthreshold amounts in one portion of a corresponding oscillation cycleand fall below threshold amounts in another portion of the correspondingoscillation cycle. Some embodiments may correspondingly cycle powergeneration using one or more inverters to compensate or otherwiseaccount for periodic changes in a power requirement.

Alternatively, or in addition, the set of electrical measurements mayinclude a current frequency measurement(s), an electrical phase sequencemeasurement(s), a power factor measurement(s), electrical harmonicsmeasurement(s) (e.g., current harmonics, voltage harmonics, or thelike), electrical inter-harmonics measurement(s), total harmonicdistortion measurement(s), measurement(s) of individual phase waveforms,or the like. For example, some embodiments may determine a phasemeasurement, a current harmonics measurement, and a total harmonicdistortion of electricity being provided to a set of controllers orother computing devices attached to an on-site well control system, alandfill control system, a wastewater treatment plant control system, orother gas emission source control systems. As discussed further below,some embodiments may use electrical measurements to detect possiblesystem issues such as faulty wiring, system damage, system misuse,system overuse, electrical overloads, or the like. For example, someembodiments may measure harmonics in an electrical line connected to avariable speed generator. A determination that a harmonic measurementexceeds a harmonic range threshold may indicate that the generator isbeing operated at a power generation rate causing generatoroscillations. Some embodiments may measure harmonic distortions or otherinterharmonic measurements and group the measurements into one or morespecific frequency ranges. These frequency ranges may then be used tocategorize or otherwise detect one or more issues based on the frequencyrange corresponding with a harmonic distortion. For example, someembodiments may determine that an electrical component of a pump iscorroded, shut down, or otherwise defective based on a determinationthat a harmonic distortion is within a first frequency range and notwithin a second frequency range. In addition, some embodiments maydetermine a total harmonic distortion based on individual frequencyrange measurements.

In some embodiments, the set of electrical measurements may includephase waveform measurements. For example, some embodiments may determinephase waveform measurements of electrical outputs by a gas generatorduring a calibration or testing phase to detect possible issues relatedto an initial setup. For example, some embodiments may detect a set oflocalized spikes in an electrical output waveform and generate a mappingbetween different types of waveforms and different types of events.Alternatively, or in addition, some embodiments may detect a phasewaveform during later power generation operations. As describedelsewhere in this disclosure, some embodiments may use these waveformmeasurements to diagnose or detect gas-related issues and updategas-related processing parameters, such as a compressor parameter orvalve parameter.

In some embodiments, multiple electric meters may be used to obtain oneor more electrical measurements at one or more positions of anintake-adaptable gas generator system. Some embodiments may providemeasurements corresponding to a total amount of AC power from thegenerator to a set of power destinations. For example, some embodimentsmay provide an amperage and the frequency of the AC power being providedby a gas generator. Some embodiments may provide electrical measurementscorresponding to the power supplied to each of a set of powerdestinations. For example, if an inverter is used to provide AC power toa set of three different components (e.g., three different DC powersupplies), some embodiments may obtain current measurements, voltagemeasurements, amperage measurements, power measurements, or otherelectrical measurements for each of the three different components. Someembodiments may provide electrical measurements corresponding to one ormore of the inverters used to convert AC power to DC power or DC powerto AC power. For example, some embodiments may provide a measurement ofthe amount of AC power supplied by a generator to an inverter and ameasurement of the amount of DC power provided by the inverter that wasconverted from the AC power. Some embodiments may provide electricalmeasurements power connections to other electrical power sources such asan electrical grid power supply, an on-site solar array, on-site batterysystem, or the like. For example, some embodiments may provide frequencymeasurements, electrical power output measurements, or other electricalmeasurements of one or more inverters connected to an electrical gridpower supply.

In some embodiments, the process 600 may include obtaining a set offluid measurements of a fluid mixture of the intake-adaptable gasgenerator system, as indicated for block 630. The set of fluidmeasurements may include measurements of absolute pressure, relativepressure, differential pressure, oxygen, fluid flow, temperature, fluidcomposition (e.g., an amount of oil, gas, or water in a tank or pipe),or the like. For example, some embodiments may obtain measurements of atemperature and pressure at a gas fluid tank and pressures of a fluid atan inflow position and outflow position of a compressor.

The set of fluid measurements may be obtained from one or more sensorsdistributed through an intake-adaptable gas generator system. Someembodiments may obtain measurements from sensors positioned acrossvalves separating different sections of an intake-adaptable gasgenerator system. For example, some embodiments may obtain measurementsof a pressure difference across a first valve between a fluid tank and acompressor used to compressed gas into a first gas fluid tank. Someembodiments may obtain measurements from sensors positioned in proximityof or inside of an electronic or mechanical component. For example, someembodiments may obtain measurements corresponding to a suction pressureof a pump, a discharge pressure of the pump, a compressor recycle value,or the like. For example, some embodiments may obtain measures of acompressor discharge pressure and a pressure of a fluid tank, where thefluid tank stores gases discharged from the compressor after passing avalve.

The set of fluid measurements may include measurements correlated with afluid composition, such as a relative measure or absolute measure of aspecific fluid, fluid type, phase of matter, or the like. For example,some embodiments may obtain a measure of the amount of oxygen (e.g., inmeasurements of parts per million) in a pipe, an open flow channel,another type of conduit, fluid tank, or another component of theintake-adaptable gas generator system. As described further below,measures of oxygen may be used to determine if an amount of gas may besafely stored or if operational parameters should be modified in caseswhere an oxygen concentration measurement exceeds a threshold.

The set of fluid measurements may include a measurement resulting fromcomputation using one or more other measurements as an input. Forexample, some embodiments may obtain a measure of centralized tendency(e.g., a mean average, a median, a mode, or the like) of pressure for afluid in a pipe, tank, or another vessel during an event, apre-determined period of time, or the like. As discussed further below,some embodiments may determine that one or more operational parametersshould be modified based on the mean average pressure or some othermeasurement.

In some embodiments, the process 600 may include determining a set ofpredicted fluid flow rates based on the set of fluid measurements, asindicated for block 640. Some embodiments may predict a fluid flow rateof a hydrocarbon well or other gas emission source based on the set offluid measurements by determining a current amount of gas beingconsumed, a current amount of gas provided to one or more fluid tanksand determining changes in either or both values over a period of time.For example, some embodiments may obtain a sequence of pressuremeasurements from a sensor that measures fluid properties of a fluidcoming out of a hydrocarbon well or other gas emission source. Based onthe pressure measurements, some embodiments may then predict fluid flowrates, as described elsewhere in this disclosure. Furthermore, someembodiments may determine a sequence of predicted power outputs based onthe set of predicted fluid flow rates using statistical ormachine-learning operations.

Various specific operations or algorithms may be used to determine apredicted fluid flow rate of fluid being extracted from a hydrocarbonwell or other gas emission source. In some embodiments, a set of valuesthat contribute to an expected fluid flow rate (i.e., “trim values”) maybe used to determine a set of predicted fluid flow rates, which may beordered over a duration as a sequence of predicted fluid flow rates.Some embodiments may determine a trim value for one or more systemfactors, where a system factor may be determined based on a measurementor parameter. For example, some embodiments may determine a first trimvalue correlating a portion of a fluid flow rate with an average mainsuction pressure, a second trim value correlating for a second portionof the fluid flow rate with a pressure of fluid coming from productionequipment, or a trim value correlating a third portion of the fluid flowrate with the pressure of a compressor liquid condensate.

In some embodiments, the effects correlated with a fluid flow rate bythe first trim value may be determined based on a measured gas generatorload, a commanded load of a gas generator, a ratio of a storage pressureto a target storage pressure, and a compressor load. For example, someembodiments may determine a quantitative value associated with the firsttrim value based on a measured gas generator load of 80%, a commandedgas generator load of 100%, astorage-pressure-to-target-storage-pressure ratio of 0.8, and acompressor load of 100%, where each value may be used to generate acombined score that is weighted by the first trim value. Someembodiments may determine the effect of the combined score empirically,such as by observing changes in the above-listed quantities anddetermining their corresponding effect on a fluid flow rate.

Some embodiments may determine effects correlated with the fluid flowrate by the second trim value based on pressure measurements ortemperature measurements. Some embodiments may observe measurementscorresponding with the start of fluid flow in a hydrocarbon well orother gas emission source, stop of fluid flow in the hydrocarbon well orother gas emission source, a peak pressure or temperature of a fluidbeing removed from the hydrocarbon well or other gas emission source, ameasure of central tendency of the measurements over a duration, or thelike. For example, some embodiments may use an empirically determinedcorrelation between average pressure or temperature measurements offluid being stored in a fluid tank and a flow rate to predict futureflow rate changes. Some embodiments may use detected changes in thepattern of the measurements (e.g., helical changes in measurements) topredict future changes in a fluid flow rate. Alternatively, or inaddition, some embodiments may determine effects correlated with thefluid flow rate by the third trim value based on pressure measurementsor temperature measurements of a liquid condensate. For example, someembodiments may determine a pressure and temperature of a liquidcondensate by using sensors attached to a liquid return line, such asthe liquid return pipe 128.

In some embodiments, trim values may be set as absolute values, relativevalues, or the like. The trim values may be used as weighting factors todetermine a magnitude of an effect on a predicted fluid flow rate. Forexample, some embodiments may normalize each of a set of system factorsto a specified predicted fluid flow rate or predicted gas contributionvariable, where changes in a normalized system factor value may beweighted by a trim value determine an updated predicted gas value usablefor determining a predicted fluid flow rate. In addition, a trim valuemay be continuously adjusted over time and may be used to adjustoperational parameters.

In some embodiments, various other weighting factors may be used topredict the effect that a measurement or set of measurements may have ona flow rate, fluid property, or another sensor measurement of anintake-adaptable gas generator system. For example, some embodiments maydetermine that a 10% increase in an amount of power being consumed by acompressor corresponds with a 15% increase in the consumption of gas. Inresponse, some embodiments may update a corresponding weighting factorto indicate that a 10% increase in the compressor load causes a 15%increase in a gas consumption rate. By providing a means of accountingfor the effect that any number or types of measurements or operationalparameters may have on a predicted fluid flow rate, some embodiments mayprovide a robust method of optimizing the performance of anintake-adaptable gas generator system.

In some embodiments, the process 600 may include determining whether aset of measurements or predicted values based on the measurementssatisfy a set of adjustment criteria based on the target value, asindicated by block 650. In some embodiments, determining whether the setof measurements satisfy the set of adjustment criteria may includedetermining whether a measurement or value computed from a measurementsatisfies a criterion based on a target value, such as matching a targetvalue, being less than a target value, being greater than a targetvalue, or the like. In response, some embodiments may determine that theadjustment threshold is satisfied. For example, a target value may be arelative target power output that includes the value “100%” to indicatethat an operational parameter of a gas generator is configured to causethe gas generator to produce power at 100% of its rated power generationcapacity (e.g., 10 kW, 50 kW, or the like). As described elsewhere inthis disclosure, differences between a measured value and a target valuemay cause one or more changes to the configuration of a gas generatorsystem. For example, if a measured power generation rate is 40 kW andthe generator's power generation capacity is recorded at 80 kW, someembodiments may determine that the generator load is at 50% and that thetarget power output does not match the measured value. In response, someembodiments may determine that the adjustment threshold is satisfied.

In some embodiments, determining whether a set of predicted values basedon the measurements satisfy an adjustment criterion may includedetermining whether a predicted power output of the sequence ofpredicted power outputs satisfies a criterion of the target poweroutput. For example, some embodiments may determine that a sequence ofpredicted power outputs includes a predicted power output equal to 300kW corresponding with a future time 8 AM. Some embodiments may determinethat the predicted power output is less than a target power output, andthus that the sequence of predicted power outputs satisfies anadjustment criterion based on the target power output. In response, someembodiments may increase an amount of fluid stored in a fluid tank, suchas by actuating a valve of the fluid tank. An increase in the amount ofstorage allocated to fluid storage may increase the time for which arequired power output may be maintained.

In some embodiments, determining whether the set of measurements satisfythe set of adjustment criteria may include determining whether anelectrical measurement satisfies an electrical measurement criterion.For example, some embodiments may determine that an adjustment criterionis satisfied in response to a determination that a harmonic measurementis outside of a harmonic range. In some embodiments, determining thatthe harmonic measurement is outside of the harmonic range may includedetermining that a total harmonic distortion is greater than a totaldistortion threshold. Alternatively, determining that the harmonicmeasurement is outside of the harmonic range may include determiningthat a total harmonic distortion is greater than a total distortionthreshold or that a specific frequency of a distortion is greater than acorresponding distortion threshold. As described elsewhere in thisdisclosure, some embodiments may consequently reduce a load on a gasgenerator, such as by reducing a gas intake amount by manipulating avalve or decreasing a compressor load.

In some embodiments, determining whether the set of measurements satisfythe set of adjustment criteria may include determining whether aconcentration or presence of a specific element or compound satisfies aset of criteria based on the target value. For example, some embodimentsmay determine whether a sulfide content of a gas satisfies a threshold,where a determination that the sulfide content of the gas satisfies thethreshold may cause the actuation of a valve to direct the gas through asulfide scrubbing module or otherwise change the flow of the gas. Insome embodiments, re-directing the flow of the gas may change anendpoint of the gas. For example, after a determination that a fluidmixture has a hydrogen sulfide concentration that is greater than asulfide threshold, some embodiments may re-direct the gas to poisonousgas fluid tank while fluids having a hydrogen sulfide concentration thatdo not satisfy the sulfide threshold may be sent to a gas pressurizer.Alternatively, or in addition, some embodiments may determine whether ahydrocarbon concentration measurement or carbon monoxide concentrationmeasurement of an exhaust gas is greater than a threshold, and, inresponse to a determination that the hydrocarbon concentrationmeasurement is greater than the threshold, increase an oxygenconcentration of a fluid mixture entering a gas generator. For example,some embodiments may determine whether an exhaust gas of a gas generatorhas a methane or ethane concentration that is greater than aconcentration threshold, such as 1%. In response to a determination thatthe exhaust gas has a methane or ethane concentration greater than 1%,some embodiments may actuate a valve or otherwise modify the state of avalve to increase the concentration of oxygen molecules in a fluidmixture provided to the gas generator.

In some embodiments, measures of a fluid property may be used to causechanges in the operations of a gas generator or set of fluid controldevices used to process fuel for the gas generator. Some embodiments maydetermine whether a nitrogen oxide measurement provided by a nitrogenoxides sensor indicates satisfaction of a nitrogen oxides concentrationthreshold. In response to a determination that a nitrogen oxidesmeasurement is greater than the nitrogen oxides concentration threshold,some embodiments may configure a set of operational parameters of gasgenerator system to reduce an engine temperature or reduce a nitrogenconcentration of gas flowing into a gas generator. For example, inresponse to a determination that a nitrogen oxides concentration isgreater than a nitrogen oxides concentration threshold, some embodimentsmay reduce a relative amount of atmospheric nitrogen in a fluid mixture.

In some embodiments, the target value may be a target fluid property,where determining whether the set of measurements satisfy the set ofadjustment criteria may include determining whether a measurement of afluid property satisfies a set of criteria based on the target fluidproperty. As described elsewhere in this disclosure, a fluid propertymay include an energy density, a mass density, a viscosity, atemperature, a pressure, a composition, or the like. For example, someembodiments may determine whether an energy density of a fluid mixturesatisfies an energy density threshold. In some embodiments, adetermination that the energy density satisfies the energy densitythreshold may cause a change in an operational parameter of a set offluid control devices to change a mixture ratio of the fluid mixture. Asdescribed elsewhere in this disclosure, changing the operationalparameter of a fluid control device may include modifying the load of acompressor, actuating a valve, increasing a pump turbine speed, or thelike. For example, some embodiments may actuate a valve to increase aflow rate of a cooled exhaust gas provided by a gas generator relativeto a flow rate of hydrocarbon gas, such as hydrocarbon gas provided by agas emission sources such as a hydro carbon well or other gas emissionsources discussed herein. As described elsewhere in this disclosure, bydiluting an input gas obtained directly from a gas emission source withexhaust gas, some embodiments may then modify the energy density of aninput fluid mixture of a gas generator to satisfy an energy densityrange of the gas generator.

In some embodiments, determining whether the set of measurements satisfythe set of adjustment criteria may include determining whether ameasurement is within a tolerance range of a set of values. For example,a target value may include the value “90%” to indicate that an adaptableintake-adaptable gas generator system is to consume at least 90% ofgases produced by a gas emission source or stored in a fluid tank. If adetermination is made that a measured gas consumption rate is 91%, someembodiments may determine that the set of adjustment criteria is notsatisfied. Alternatively, if a determination is made that a measured gasconsumption rate is 89%, some embodiments may determine that the set ofadjustment criteria is satisfied. If the set of adjustment criteria issatisfied, operations of the process 600 may proceed to operationsdescribed by block 655. Otherwise, operations of the process 600 mayreturn to operations described by block 620 or may end. Furthermore,some embodiments may first determine whether a criterion based on atarget value is satisfied earlier in the process 600, such as afterdetermining the target value as described for block 610, obtaining theset of electrical measurements as described for block 620, obtaining theset of fluid measurements as described for block 630, or the like. Inresponse to a determination that the criterion based on the target valueis satisfied, some embodiments may proceed without modifying one or moreoperational parameters of an intake-adaptable gas generator system.

In some embodiments, the process 600 may include determining a set ofoperational parameters based on the target value, as indicated for block655. As discussed above, some embodiments may normalize a set ofmeasurements, computation results based on measurements, operationalparameter(s), target value(s), or the like. Some embodiments maydetermine the effect that a change in a measurement or parameter mayhave on another measurement or parameter using a weighting value(sometimes known as a “trim” value or trim weight). By determining theeffect that a change in a may have on a variable using weights, someembodiments may represent the relationship between a manipulatableoperational parameter and a set of measurements or target values as alinear system, where iterative optimization may be used to determinewhat operational parameters to change in order to satisfy one or morecriteria based on a set of target values.

Some embodiments may use one or more sets of upper-bound thresholds orlower-bound thresholds for one or more of the measurements orparameters. For example, some embodiments may include a compressor loadas an operational parameter that may be changed to satisfy a criterionbased on a target value, such as a target power generation rate or atarget gas consumption rate. The compressor load may have an upper-boundthreshold of 500 Watts (W) and a lower-bound threshold of 5 W toindicate that the compressor may not be adjusted to consume more than500 W or less than 5 W during operations of the intake-adaptable gasgenerator system. In response to a determination that a measured powerconsumption is greater than the upper-bound threshold or less than alower-bound threshold, some embodiments may then change a compressorconfiguration, as described elsewhere in this disclosure.

Some embodiments may generate a sequence of operational parametersassociated with different kinds or operational conditions. For example,some embodiments may generate a sequence of compressor load values ordigital valve control values to increase a gas tank storage pressure,which may increase an amount of gas to be sent into a gas generator. Forexample, after determining a sequence of predicted fluid flow rates fora future 10-hour duration, some embodiments may then perform a set ofiterative optimization operations (e.g., a stationary iterative method,Krylov subspace methods, or the like) to determine a correspondingsequence of operational parameters to satisfy a criterion based on atarget value. For example, some embodiments may determine a sequence ofcompressor pumping loads to satisfy a criterion based on a target valuesuch as “100%,” which may include a criterion that a gas generator is toconsume 100% of gases being produced from a hydrocarbon well or othergas emission source, where the sequence of compressor pumping loads maychange in correlation with a sequence of predicted fluid flow rates thatindicate an increase in the amount of gas over a 5 hour duration.Furthermore, while the above describes iterative optimizationoperations, machine-learning operations or other operations usable tosolve a linear or nonlinear system to satisfy a set of criteria based ona set of target values may be used to configure an intake-adaptable gasgenerator system.

In some embodiments, the process 600 may include actuating or otherwisemodifying the state of a set of fluid control devices based on the setof operational parameters, as indicated by block 660. As describedelsewhere in this disclosure, some embodiments may actuate or otherwisemodify the state of a fluid control device based on a set of operationalparameters in response to changes in a set of measurements. In someembodiments, modifying a fluid control device may include directlysetting a digital input of a control system to the parameter. Forexample, the parameter may comprise the value 1.0 that may then beconverted to a digital value such as “100”, which may then be sent to acompressor to cause the compressor to operate at a compressor load equalto 100%. Alternatively, or in addition, the parameter may include adimensionalized value, such as 10 cubic meters per second, where thedimensionalized value may be used to modify a fluid control device.

In some embodiments, modifying the state of a fluid control device mayinclude modifying the configuration of a fluid tank or other fluidcontrol device to satisfy a set of operational parameters determinedfrom one or more predicted values. For example, an operational parametermay include a storage capacity, where the storage capacity is determinedto be less than a threshold capacity, where the threshold capacity maybe based on a possible or predicted increase in gas being produced by ahydrocarbon well, tank, or another gas emission source. In response,some embodiments may modify a fluid control device to reduce a fluidtank pressure or decrease a storage pressure load to increase a fluidstorage capacity of a fluid tank, or otherwise satisfy a gas storagecapacity threshold.

In some embodiments, modifying the fluid control system may includemodifying a set of fluid control devices to satisfy an operational mode,such as consuming all of the gas being produced by a hydrocarbon well orother gas emission source. For example, a set of fluid control devicesmay be determined using one or more of the operations described above tostore or use all of the gas being produced by a hydrocarbon well orother gas emission source. Some embodiments may then perform operationssuch as increase the amount of gas being stored in a storage chamber,increasing a fluid tank pressure, increasing a compressor load, or thelike based on the set of fluid control devices. For example, based on adetected pressure increase or a detected rate of the pressure increase,some embodiments may increase a compressor parameter, such as acompressor speed.

In some embodiments, modifying the fluid control system may includemodifying a set of fluid tanks based on a pressure change. For example,modifying the fluid control system may include modifying a gas storagevalve or a compressor operational parameter to increase a gas tankpressure to capture an incoming gas peak, where an incoming gas peak maybe the result of a natural phenomenon, an accident, or an operationalchange at a gas well or other gas emission source. Alternatively, someembodiments may detect a temperature change and reduce a gas pressure byreducing a gas compressor load. Furthermore, some embodiments maymeasure a consistency of pressure or temperature measurements and modifya fluid tank parameter based on the consistency. For example, someembodiment may determine a pressure or temperature variance and, inresponse to the variance satisfying a variance threshold, update thevariance. Alternatively, or in addition, some embodiments may actuate avalve or adjust a temperature of a fluid tank or other component toincrease an amount of condensate that is recovered from a fluid mixture.

As described elsewhere in this disclosure, a gas supply provided by ahydrocarbon well or other gas emission source may be inconsistent andprovide less gas than predicted or more gas than predicted. Someembodiments may detect that a fluid flow rate is lower than an expectedvalue. In response, some embodiments may reduce a generator speed orother generator-controlling parameter of a gas generator to reducehydrocarbon consumption. By reducing a generator-controlling parameter,some embodiments may cool the gas generator and reduce mechanicaldegradation of the gas generator. Similarly, some embodiments mayactuate a valve or change a compressor speed to decrease an energydensity of a fluid mixture in response to a determination that a fluidmixture has an energy density measurement that is greater than an energydensity threshold. For example, some embodiments may increase acompressor recycle amount (i.e., the amount of fluid that is dischargedfrom the compressor that is then directly fed back into an inlet of thecompressor) in response to a detected differential pressure measurement.

Various other operational parameters (e.g., an operational parameterthat controls a gas flow rate, a pressure of a section of a gasgenerator system, or the like) may be modified in response to a set ofmeasurements satisfying a set of criteria. Such measurements may includemeasurements discharge amounts, suction pressures, or differentialpressure measurements of a fluid tank. For example, some embodiments maydetermine that a specific frequency of a distortion is greater than adistortion threshold and, in response, reduce a load on a gas generatorby increasing a flow rate of carbon dioxide from exhaust gas relative togas from a hydrocarbon well or other gas emission source. By increasingthe exhaust gas flow rate, the ratio of carbon dioxide to hydrocarbongas may increase, which may consequently reduce the load on a generator.

In some embodiments, a set of fluid control devices may be configuredbased on fluid measurements. For example, a pressure sensor of ahydrocarbon well or other gas emission source may be monitored toincrease a compressor capacity in response to a predicted pressureincrease of a fluid tank. Some embodiments may adjust a trim value byperforming operations such as normalizing an average pressure,determining a parameter based on a duration of an event, determine aflow rate change based on a tank pressure increase, or the like. Someembodiments may scale an event's effects based on a measured slope or anaverage value. By determining averages or otherwise permitting previousmeasurements to modify a trim value impact of a current measurement,some embodiments may reduce or increase the effect that the currentmeasurement has on a parameter of a generator, compressor, valve, orother fluid control device. In addition, some embodiments may actuate adump valve on a fluid tank, such as a scrubber tank, to injecthydrocarbon gas into the fluid tank from a compressed gas supply fromthe secondary tank. In some embodiments, the rapid injection ofhydrocarbon gas into a fluid tank may reduce the risk of equipmentfailure from sudden changes in pressure, such as during tank depletionevents caused by gas removal.

As described elsewhere in this disclosure, some embodiments may modifythe state of a fluid control device based on a measurement of a chemicalpresence or concentration. Some embodiments may obtain oxygenmeasurements from an oxygen sensor in a pipe or another conduit that isused to deliver gas or other fluids. In some embodiments, a detectedoxygen measurement may cause the actuation of a valve to increase theinjection rate of oxygen from an oxygen source into the pipe.Furthermore, some embodiments may determine that an amount of oxygen isgreater than a threshold and, in response, stop the flow of ahydrocarbon fluid out of a fluid tank or purge the fluid tank withhydrocarbon gas. Alternatively, or in addition, some embodiments maymodify the state of a fluid control device based on a detection of anitrogen oxide, such as nitrogen dioxide or nitrogen trioxide. Forexample, some embodiments may determine that a detected nitrogen dioxidemeasurement is greater than a concentration threshold and, in response,reduce a flow rate of atmospheric air into a fluid mixture that is thenprovided to a gas generator via an inlet. Alternatively, or in addition,some embodiments may increase a flow rate of an inert gas to a generatorinlet relative to the atmospheric nitrogen.

Furthermore, as described elsewhere in this disclosure, some embodimentsmay detect an electrical measurement, such as a set of harmonicmeasurements, and adjust the operation of a fluid control device inresponse to the electrical measurement. For example, some embodimentsmay obtain a set of electrical measurements of electrical energygenerated by a gas generator and determine that the set of electricalmeasurements satisfies a set of measurement criteria indicating aflagged harmonic distortion or another type of flagged harmonic. Inresponse to a determination that a set of measurements indicates aflagged harmonic, some embodiments may reduce a gas generator speed. Insome embodiments, reducing a gas generator speed may include actuating avalve to reduce the amount of a fluid mixture being provided to the gasgenerator for combustion or increasing an amount of carbon dioxide gasin the input fluid mixture. For example, some embodiments may increase afirst flow rate relative to a second flow rate, where the first flowrate is the rate at which exhaust gas is sent into a compressor inlet,and where the second flow rate is the rate at which non-recycled gassent from a hydrocarbon well or other gas emission source is sent to thecompressor inlet.

As described elsewhere in this disclosure, some embodiments may apply aplurality of criteria having different associated thresholds andassociated with different types of measurements. For example, someembodiments may perform ride-through operations, such that someembodiments may effect no changes in the parameters or states ofcomponents of an intake-adaptable gas generator while measurements arewithin the dead bands of a set of target values, where each respectivedead band of a target value may have different ranges or units. Inaddition, some embodiments may include a set of safety thresholds thatare shared between different operational modes. For example, someembodiments may include a first operational mode that causes anintake-adaptable gas generator system to generate power for on-siteoperations and a second operational mode to maximize electricitygeneration, where both modes share a criterion to stop operations if atemperature satisfies a safety threshold.

FIG. 7 shows an example of a computing device by which the presenttechniques may be implemented, in accordance with some embodiments.Various portions of systems and methods described herein, may include orbe executed on one or more computer systems similar to computer system700. Further, processes and modules described herein, such as one ormore operations described for the process 600, may be executed by one ormore processing systems similar to that of computer system 700.

Computer system 700 may include one or more processors (e.g., processors710 a-710 n) coupled to System memory 720, an input/output I/O deviceinterface 730, and a network interface 740 via an input/output (I/O)interface 750. A processor may include a single processor or a pluralityof processors (e.g., distributed processors). A processor may be anysuitable processor capable of executing or otherwise performinginstructions. A processor may include a central processing unit (CPU)that carries out program instructions to perform the arithmetical,logical, and input/output operations of computer system 700. A processormay execute code (e.g., processor firmware, a protocol stack, a databasemanagement system, an operating system, or a combination thereof) thatcreates an execution environment for program instructions. A processormay include a programmable processor. A processor may include general orspecial purpose microprocessors. A processor may include one or moremicrocontrollers. A processor may receive instructions and data from amemory (e.g., System memory 720). Computer system 700 may be auni-processor system including one processor (e.g., processor 710 a), ora multi-processor system including any number of suitable processors(e.g., 710 a-710 n). Multiple processors may be employed to provide forparallel or sequential execution of one or more portions of thetechniques described herein. Processes, such as logic flows, describedherein may be performed by one or more programmable processors executingone or more computer programs to perform functions by operating on inputdata and generating corresponding output. Processes described herein maybe performed by, and apparatus can also be implemented as, specialpurpose logic circuitry, e.g., an FPGA (field programmable gate array)or an ASIC (application specific integrated circuit). Computer system700 may include a plurality of computing devices (e.g., distributedcomputer systems) to implement various processing functions.

I/O device interface 730 may provide an interface for connection of oneor more I/O devices 760 to computer system 700. I/O devices may includedevices that receive input (e.g., from a user) or output information(e.g., to a user). I/O devices 760 may include, for example, graphicaluser interface presented on displays (e.g., a cathode ray tube (CRT) orliquid crystal display (LCD) monitor), pointing devices (e.g., acomputer mouse or trackball), keyboards, keypads, touchpads, scanningdevices, voice recognition devices, gesture recognition devices,printers, audio speakers, microphones, cameras, or the like. I/O devices760 may be connected to computer system 700 through a wired or wirelessconnection. I/O devices 760 may be connected to computer system 700 froma remote location. I/O devices 760 located on remote computer system,for example, may be connected to computer system 700 via a network andnetwork interface 740.

Network interface 740 may include a network adapter that provides forconnection of computer system 700 to a network. Network interface may740 may facilitate data exchange between computer system 700 and otherdevices connected to the network. Network interface 740 may supportwired or wireless communication. The network may include an electroniccommunication network, such as the Internet, a local area network (LAN),a wide area network (WAN), a cellular communications network, or thelike.

System memory 720 may be configured to store program instructions 724 ordata 710. Program instructions 724 may be executable by a processor(e.g., one or more of processors 710 a-710 n) to implement one or moreembodiments of the present techniques. Program instructions 724 mayinclude modules of computer program instructions for implementing one ormore techniques described herein with regard to various processingmodules. Program instructions may include a computer program (which incertain forms is known as a program, software, software application,script, or code). A computer program may be written in a programminglanguage, including compiled or interpreted languages, or declarative orprocedural languages. A computer program may include a unit suitable foruse in a computing environment, including as a stand-alone program, amodule, a component, or a subroutine. A computer program may or may notcorrespond to a file in a file system. A program may be stored in aportion of a file that holds other programs or data (e.g., one or morescripts stored in a markup language document), in a single filededicated to the program in question, or in multiple coordinated files(e.g., files that store one or more modules, sub programs, or portionsof code). A computer program may be deployed to be executed on one ormore computer processors located locally at one site or distributedacross multiple remote sites and interconnected by a communicationnetwork.

System memory 720 may include a tangible program carrier having programinstructions stored thereon. A tangible program carrier may include anon-transitory, computer-readable storage medium. A non-transitory,computer-readable storage medium may include a machine readable storagedevice, a machine readable storage substrate, a memory device, or anycombination thereof. Non-transitory, computer-readable storage mediummay include non-volatile memory (e.g., flash memory, ROM, PROM, EPROM,EEPROM memory), volatile memory (e.g., random access memory (RAM),static random access memory (SRAM), synchronous dynamic RAM (SDRAM)),bulk storage memory (e.g., CD-ROM and/or DVD-ROM, hard-drives), or thelike. System memory 720 may include a non-transitory, computer-readablestorage medium that may have program instructions stored thereon thatare executable by a computer processor (e.g., one or more of processors710 a-710 n) to cause the subject matter and the functional operationsdescribed herein. A memory (e.g., System memory 720) may include asingle memory device and/or a plurality of memory devices (e.g.,distributed memory devices). Instructions or other program code toprovide the functionality described herein may be stored on a tangible,non-transitory, computer-readable media. In some cases, the entire setof instructions may be stored concurrently on the media, or in somecases, different parts of the instructions may be stored on the samemedia at different times.

I/O interface 750 may be configured to coordinate I/O traffic betweenprocessors 710 a-710 n, System memory 720, network interface 740, I/Odevices 760, and/or other peripheral devices. I/O interface 750 mayperform protocol, timing, or other data transformations to convert datasignals from one component (e.g., System memory 720) into a formatsuitable for use by another component (e.g., processors 710 a-710 n).I/O interface 750 may include support for devices attached throughvarious types of peripheral buses, such as a variant of the PeripheralComponent Interconnect (PCI) bus standard or the Universal Serial Bus(USB) standard.

Embodiments of the techniques described herein may be implemented usinga single instance of computer system 700 or multiple computer systems700 configured to host different portions or instances of embodiments.Multiple computer systems 700 may provide for parallel or sequentialprocessing/execution of one or more portions of the techniques describedherein.

Those skilled in the art will appreciate that computer system 700 ismerely illustrative and is not intended to limit the scope of thetechniques described herein. Computer system 700 may include anycombination of devices or software that may perform or otherwise providefor the performance of the techniques described herein. For example,computer system 700 may include or be a combination of a cloud-computingsystem, a data center, a server rack, a server, a virtual server, adesktop computer, a laptop computer, a tablet computer, a server device,a client device, a mobile telephone, a personal digital assistant (PDA),a mobile audio or video player, a game console, a vehicle-mountedcomputer, or a GPS device, or the like. Computer system 700 may also beconnected to other devices that are not illustrated, or may operate as astand-alone system. In addition, the functionality provided by theillustrated components may in some embodiments be combined in fewercomponents or distributed in additional components. Similarly, in someembodiments, the functionality of some of the illustrated components maynot be provided or other additional functionality may be available.

Those skilled in the art will also appreciate that while various itemsare illustrated as being stored in memory or on storage while beingused, these items or portions of them may be transferred between memoryand other storage devices for purposes of memory management and dataintegrity. Alternatively, in other embodiments some or all of thesoftware components may execute in memory on another device andcommunicate with the illustrated computer system via inter-computercommunication. Some or all of the system components or data structuresmay also be stored (e.g., as instructions or structured data) on acomputer-accessible medium or a portable article to be read by anappropriate drive, various examples of which are described above. Insome embodiments, instructions stored on a computer-accessible mediumseparate from computer system 700 may be transmitted to computer system700 via transmission media or signals such as electrical,electromagnetic, or digital signals, conveyed via a communication mediumsuch as a network or a wireless link. Various embodiments may furtherinclude receiving, sending, or storing instructions or data implementedin accordance with the foregoing description upon a computer-accessiblemedium. Accordingly, the present techniques may be practiced with othercomputer system configurations.

In block diagrams, illustrated components are depicted as discretefunctional blocks, but embodiments are not limited to systems in whichthe functionality described herein is organized as illustrated. Thefunctionality provided by each of the components may be provided bysoftware or hardware modules that are differently organized than ispresently depicted, for example such software or hardware may beintermingled, conjoined, replicated, broken up, distributed (e.g. withina data center or geographically), or otherwise differently organized.The functionality described herein may be provided by one or moreprocessors of one or more computers executing code stored on a tangible,non-transitory, machine readable medium. In some cases, notwithstandinguse of the singular term “medium,” the instructions may be distributedon different storage devices associated with different computingdevices, for instance, with each computing device having a differentsubset of the instructions, an implementation consistent with usage ofthe singular term “medium” herein. In some cases, third party contentdelivery networks may host some or all of the information conveyed overnetworks, in which case, to the extent information (e.g., content) issaid to be supplied or otherwise provided, the information may beprovided by sending instructions to retrieve that information from acontent delivery network.

The reader should appreciate that the present application describesseveral independently useful techniques. Rather than separating thosetechniques into multiple isolated patent applications, applicants havegrouped these techniques into a single document because their relatedsubject matter lends itself to economies in the application process. Butthe distinct advantages and aspects of such techniques should not beconflated. In some cases, embodiments address all of the deficienciesnoted herein, but it should be understood that the techniques areindependently useful, and some embodiments address only a subset of suchproblems or offer other, unmentioned benefits that will be apparent tothose of skill in the art reviewing the present disclosure. Due to costsconstraints, some techniques disclosed herein may not be presentlyclaimed and may be claimed in later filings, such as continuationapplications or by amending the present claims. Similarly, due to spaceconstraints, neither the Abstract nor the Summary of the Inventionsections of the present document should be taken as containing acomprehensive listing of all such techniques or all aspects of suchtechniques.

It should be understood that the description and the drawings are notintended to limit the present techniques to the particular formdisclosed, but to the contrary, the intention is to cover allmodifications, equivalents, and alternatives falling within the spiritand scope of the present techniques as defined by the appended claims.Further modifications and alternative embodiments of various aspects ofthe techniques will be apparent to those skilled in the art in view ofthis description. Accordingly, this description and the drawings are tobe construed as illustrative only and are for the purpose of teachingthose skilled in the art the general manner of carrying out the presenttechniques. It is to be understood that the forms of the presenttechniques shown and described herein are to be taken as examples ofembodiments. Elements and materials may be substituted for thoseillustrated and described herein, parts and processes may be reversed oromitted, and certain features of the present techniques may be utilizedindependently, all as would be apparent to one skilled in the art afterhaving the benefit of this description of the present techniques.Changes may be made in the elements described herein without departingfrom the spirit and scope of the present techniques as described in thefollowing claims. Headings used herein are for organizational purposesonly and are not meant to be used to limit the scope of the description.

As used throughout this application, the word “may” is used in apermissive sense (i.e., meaning having the potential to), rather thanthe mandatory sense (i.e., meaning must). The word “set” when used as anoun include a single item or a plurality of items, such that the phrase“set of items” may refer to either a single item or multiple items. Thewords “include”, “including”, and “includes” and the like meanincluding, but not limited to. As used throughout this application, thesingular forms “a,” “an,” and “the” include plural referents unless thecontent explicitly indicates otherwise. Thus, for example, reference to“an element” or “an element” includes a combination of two or moreelements, notwithstanding use of other terms and phrases for one or moreelements, such as “one or more.” The term “or” is, unless indicatedotherwise, non-exclusive, i.e., encompassing both “and” and “or.” Termsdescribing conditional relationships, e.g., “in response to X, Y,” “uponX, Y,”, “if X, Y,” “when X, Y,” and the like, encompass causalrelationships in which the antecedent is a necessary causal condition,the antecedent is a sufficient causal condition, or the antecedent is acontributory causal condition of the consequent, e.g., “state X occursupon condition Y obtaining” is generic to “X occurs solely upon Y” and“X occurs upon Y and Z.” Such conditional relationships are not limitedto consequences that instantly follow the antecedent obtaining, as someconsequences may be delayed, and in conditional statements, antecedentsare connected to their consequents, e.g., the antecedent is relevant tothe likelihood of the consequent occurring. Statements in which aplurality of attributes or functions are mapped to a plurality ofobjects (e.g., one or more processors performing steps A, B, C, and D)encompasses both all such attributes or functions being mapped to allsuch objects and subsets of the attributes or functions being mapped tosubsets of the attributes or functions (e.g., both all processors eachperforming steps A-D, and a case in which processor 1 performs step A,processor 2 performs step B and part of step C, and processor 3 performspart of step C and step D), unless otherwise indicated. Further, unlessotherwise indicated, statements that one value or action is “based on”another condition or value encompass both instances in which thecondition or value is the sole factor and instances in which thecondition or value is one factor among a plurality of factors. Unlessotherwise indicated, statements that “each” instance of some collectionhave some property should not be read to exclude cases where someotherwise identical or similar members of a larger collection do nothave the property, i.e., each does not necessarily mean each and every.Limitations as to sequence of recited steps should not be read into theclaims unless explicitly specified, e.g., with explicit language like“after performing X, performing Y,” in contrast to statements that mightbe improperly argued to imply sequence limitations, like “performing Xon items, performing Y on the X′ed items,” used for purposes of makingclaims more readable rather than specifying sequence. Statementsreferring to “at least Z of A, B, and C,” and the like (e.g., “at leastZ of A, B, or C”), refer to at least Z of the listed categories (A, B,and C) and do not require at least Z units in each category. Unlessspecifically stated otherwise, as apparent from the discussion, it isappreciated that throughout this specification discussions utilizingterms such as “processing,” “computing,” “calculating,” “determining” orthe like refer to actions or processes of a specific apparatus, such asa special purpose computer or a similar special purpose electronicprocessing/computing device. Features described with reference togeometric constructs, like “parallel,” “perpendicular/orthogonal,”“square”, “cylindrical,” and the like, should be construed asencompassing items that substantially embody the properties of thegeometric construct, e.g., reference to “parallel” surfaces encompassessubstantially parallel surfaces. The permitted range of deviation fromPlatonic ideals of these geometric constructs is to be determined withreference to ranges in the specification, and where such ranges are notstated, with reference to industry norms in the field of use, and wheresuch ranges are not defined, with reference to industry norms in thefield of manufacturing of the designated feature, and where such rangesare not defined, features substantially embodying a geometric constructshould be construed to include those features within 15% of the definingattributes of that geometric construct. The terms “first”, “second”,“third,” “given” and so on, if used in the claims, are used todistinguish or otherwise identify, and not to show a sequential ornumerical limitation. As is the case in ordinary usage in the field,data structures and formats described with reference to uses salient toa human need not be presented in a human-intelligible format toconstitute the described data structure or format, e.g., text need notbe rendered or even encoded in Unicode or ASCII to constitute text;images, maps, and data-visualizations need not be displayed or decodedto constitute images, maps, and data-visualizations, respectively;speech, music, and other audio need not be emitted through a speaker ordecoded to constitute speech, music, or other audio, respectively.Computer implemented instructions, commands, and the like are notlimited to executable code and can be implemented in the form of datathat causes functionality to be invoked, e.g., in the form of argumentsof a function or API call.

In this patent, to the extent any U.S. patents, U.S. patentapplications, or other materials (e.g., articles) have been incorporatedby reference, the text of such materials is only incorporated byreference to the extent that no conflict exists between such materialand the statements and drawings set forth herein. In the event of suchconflict, the text of the present document governs, and terms in thisdocument should not be given a narrower reading in virtue of the way inwhich those terms are used in other materials incorporated by reference.

Additional detail regarding some embodiments may be described in thefollowing:

1. A system comprising: a gas generator to generate electrical energyusing a fluid mixture obtained via a generator inlet of the gasgenerator, wherein a portion of the fluid mixture comprises gas providedby a gas emission source; a compressor, wherein a compressor inlet ofthe compressor is attached to a generator outlet of the gas generator bya first set of conduits, and wherein exhaust fluid of the gas generatoris provided to the compressor via the first set of conduits, and whereinthe first set of conduits comprises a conduit attached to the gasemission source; a second set of conduits connecting a compressor outletof the compressor to the generator inlet; a sensor attached to thesecond set of conduits, wherein the sensor measures fluid properties offluids flowing through a portion of the second set of conduits; anon-transitory, machine-readable medium of storing instructions that,when executed by a computer system, effectuate operations comprising:obtaining, with the computer system, a target fluid property of thefluid mixture entering the generator inlet; obtaining, with the computersystem, a fluid measurement of the fluid mixture using the sensor;determining, with the computer system, whether the fluid measurementsatisfies a criterion based on the target fluid property; and inresponse to a determination that the target fluid property satisfies thecriterion, modifying, with the computer system, an operational parameterof a set of fluid control devices to increase a first flow rate relativeto a second flow rate, wherein the first flow rate is a measurement ofthe flow of the exhaust fluid through the second set of conduits, andwherein the second flow rate is a measurement of the flow of the gasprovided by the gas emission source through the first set of conduits.2. The system of embodiment 1, wherein the set of fluid control devicescomprises at least one of the compressor or a valve attached to thefirst set of conduits, and wherein the gas emission source includes atleast one of a hydrocarbon well, a landfill, or an anaerobic digester.3. The system of any of embodiments 1 to 2, further comprising: a heatexchanger, wherein the heat exchanger is connected to the gas generatorby the first set of conduits, and wherein the exhaust fluid of the gasgenerator is sent to the heat exchanger via the first set of conduits,and wherein the heat exchanger comprises a third set of conduits, theoperations further comprising: determining whether a temperature of theexhaust fluid flowing through an outlet of the heat exchanger satisfiesa threshold; and in response to a determination that the temperature ofthe exhaust fluid satisfies the threshold, increasing a water flowthrough the third set of conduits.4. The system of any of embodiments 1 to 3, the operations furthercomprising: obtaining a harmonics measurement of the gas generator;determining whether the harmonics measurement satisfies a threshold; andin response to a determination that the harmonics measurement satisfiesthe threshold, actuating a valve attached to the generator inlet toreduce a gas flow through the generator inlet.5. The system of any of embodiments 1 to 4, wherein the generator inletis a first generator inlet, and wherein the gas generator comprises asecond generator inlet to receive fluid from atmospheric air, the systemfurther comprising: a first conduit connected to the second generatorinlet; a valve attached to the first conduit, wherein the valve isattached a second conduit; a gas source, wherein the gas source isattached to the second conduit, the operations further comprising:determining whether the fluid measurement obtained by the sensorsatisfies a threshold; and in response to a determination that the fluidmeasurement obtained by the sensor satisfies the threshold, actuate thevalve to increase a flow of an inert gas from the gas source to the gasgenerator.6. The system of any of embodiments 1 to 5, further comprising: a firstfluid tank, wherein fluid from the compressor is pumped to the firstfluid tank; a first conduit of the second set of conduits, wherein thefirst conduit is attached to the first fluid tank at a first attachmentpoint of the first fluid tank; and a second fluid tank connected to thefirst fluid tank via the first conduit, wherein: the first conduit isattached to the second fluid tank via a second attachment point of thesecond fluid tank; the second attachment point is greater in heightrelative to the first attachment point; and the second fluid tank isconnected to the generator inlet via a third conduit of the second setof conduits.7. The system of embodiment 6, wherein the sensor is a first sensor, thesystem further comprising a second sensor attached to the first fluidtank, the operations further comprising: obtaining a measurement of aheight of a liquid in the first fluid tank based on the second sensor;determining whether the measurement of the height of the liquidsatisfies a threshold; and in response to a determination that themeasurement of the height satisfies the threshold, actuating a valveattached to a fluid outlet of the second fluid tank, wherein the fluidoutlet is lower in height than the first attachment point.8. The system of any of embodiments 1 to 7, wherein the sensor is afirst sensor, the operations further comprising: obtaining a nitrogenoxide measurement from a second sensor, wherein the second sensormeasures the exhaust fluid; determining whether the nitrogen oxidemeasurement satisfies an adjustment criterion; and in response to adetermination that the nitrogen oxide measurement satisfies theadjustment criterion, actuating a valve to reduce a flow rate ofatmospheric air that is flowing into the gas generator.9. The system of any of embodiments 1 to 8, the system furthercomprising a temperature sensor to measure the exhaust fluid, theoperations further comprising: determining whether a temperaturemeasurement of the temperature sensor satisfies a threshold; and inresponse to a determination that the temperature measurement satisfiesthe threshold, actuating a valve to reduce the flow rate of the fluidmixture flowing into the gas generator.10. The system of any of embodiments 1 to 9, the operations furthercomprising: determining whether an energy density of a recycled fluidmixture flowing from the compressor satisfies a threshold; and inresponse to a determination that the energy density of the recycledfluid mixture satisfies the threshold, actuating a valve of a secondconduit of the gas generator to increase an amount of exhaust fluidflowing into the generator inlet.11. The system of any of embodiments 1 to 10, further comprising a gaspressurizer, wherein the exhaust fluid generated by the gas generator issent to the gas pressurizer via a third set of conduits, the operationsfurther comprising: increasing a pressure of the exhaust fluid in thegas pressurizer to generate liquid carbon dioxide; and reducing apressure of the liquid carbon dioxide in the gas pressurizer to generatesolid carbon dioxide.12. The system of embodiment 11, the operations further comprising:determining a sulfide content of the exhaust fluid; determining whetherthe sulfide content of the exhaust fluid satisfies a threshold; and inresponse to a determination that the sulfide content of the exhaustfluid satisfies the threshold, reducing an amount of exhaust fluidprovided to the gas pressurizer.13. The system of any of embodiments 1 to 12, the system furthercomprising a valve, wherein: the valve controls a flow rate of theexhaust fluid to the atmosphere; and the operations further comprise:determining whether a pressure difference between a pressure of a fluidflowing through the generator outlet satisfies a threshold; and inresponse to a determination that the pressure difference satisfies thethreshold, actuating the valve to send the exhaust fluid flowing throughthe first set of conduits to the atmosphere.14. The system of any of embodiments 1 to 13, wherein the sensor is afirst sensor, the system further comprising: an evaporator that isconnected to the generator outlet via a subset of conduits of the firstset of conduits; an exhaust bypass valve, wherein the exhaust bypassvalve controls an amount of water send to the evaporator, the operationsfurther comprising: determining that a fluid property measured by asecond sensor of the evaporator satisfies a threshold; and in responseto a determination that the fluid property satisfies the threshold,increasing a water flow through a third set of conduits by actuating theexhaust bypass valve, wherein the water flowing through the third set ofconduits is at a lesser temperature than the exhaust fluid flowing intothe evaporator.15. The system of embodiment 14, further comprising: a second set oftanks, wherein the second set of tanks receives fluid from theevaporator; a filter to collect solids of the fluid in the second set oftanks; a third set of tanks, wherein the third set of tanks receivefiltered fluid from the second set of tanks; and a third conduitconnecting the third set of tanks to the evaporator.16. The system of any of embodiments 1 to 15, further comprising a gassource, wherein: the gas source is connected to the generator inlet viaa valve; and the operations further comprise: determining whether ahydrocarbon concentration measurement of fluid flowing through thegenerator outlet satisfies a threshold; and in response to adetermination that the hydrocarbon concentration measurement satisfiesthe threshold, actuating the valve to increase an amount of oxygenflowing from the gas source.17. The system of any of embodiments 1 to 16, the operations furthercomprising: obtaining a target power output; obtaining a set ofelectrical measurements for a set of components electrically connectedto the gas generator, wherein the set of electrical measurementscomprises a current measurement or a voltage measurement; whereinobtaining the fluid measurement comprises obtaining a sequence ofpressure measurements using the sensor; determining a set of predictedfluid flow rates based on the sequence of pressure measurements;determining a sequence of predicted power outputs based on the set ofpredicted fluid flow rates; determining whether a predicted power outputof the sequence of predicted power outputs satisfies a criterion of thetarget power output; and actuating a valve attached to a fluid tank inresponse to a determination that the predicted power output does notsatisfy the criterion based on the target power output, wherein thefluid tank is connected to the generator inlet.18. The system of any of embodiments 1 to 17, wherein the operationalparameter is a first parameter, and wherein the sensor is a firstsensor, the operations further comprising: obtaining a target gasconsumption amount; wherein obtaining the fluid measurement comprisesobtaining a sequence of pressure measurements using a second sensorattached to the gas emission source; determining a set of predictedfluid flow rates based on the sequence of pressure measurements;determining a second parameter based on the set of predicted fluid flowrates and the target gas consumption amount; and configuring the set offluid control devices based on the second parameter.19. The system of embodiment 18, the operations further comprising:determining that the set of predicted fluid flow rates indicate anincrease in the amount of gas to be received from the gas emissionsource; increasing an allowable storage pressure of a fluid tankconnected to the gas generator by a third set of conduits based on theincrease in the amount of gas to be received from the gas emissionsource.20. A method comprising: obtaining, with a computer system, a targetfluid property of a fluid mixture entering a generator inlet of a gasgenerator, wherein: the gas generator generates electrical energy usingthe fluid mixture obtained via the generator inlet, a portion of thefluid mixture comprises gas provided by a gas emission source, acompressor inlet of a compressor is attached to a generator outlet ofthe gas generator by a first set of conduits, exhaust fluid of the gasgenerator is provided to the compressor via the first set of conduits; asecond set of conduits connects a compressor outlet of the compressor tothe generator inlet; and a sensor measures fluid properties of fluidsflowing through a portion of the second set of conduits; obtaining, withthe computer system, a fluid measurement of the fluid mixture using thesensor; determining, with the computer system, whether the fluidmeasurement satisfies a criterion based on the target fluid property;and in response to a determination that the target fluid propertysatisfies the criterion, modifying, with the computer system, anoperational parameter of a set of fluid control devices to increase afirst flow rate relative to a second flow rate, wherein the first flowrate is a measurement of the flow of the exhaust fluid through the firstset of conduits, and wherein the second flow rate is a measurement ofthe flow of the gas provided by the gas emission source through thefirst set of conduits.21. The method of embodiment 20, wherein the set of fluid controldevices comprises at least one of the compressor or a valve attached tothe first set of conduits, and wherein the gas emission source includesat least one of a hydrocarbon well, a landfill, or an anaerobicdigester.22. The method of any of embodiments 20 to 21, the method furthercomprising: determining whether an energy density of a recycled fluidmixture flowing from the compressor satisfies a threshold; and inresponse to a determination that the energy density of the recycledfluid mixture satisfies the threshold, actuating a valve of a secondconduit of the gas generator to increase an amount of exhaust fluidflowing into the generator inlet.23. The method of any of embodiments 20 to 22, further comprising:determining whether a temperature of the exhaust fluid flowing throughan outlet of a heat exchanger satisfies a threshold, wherein the heatexchanger is connected to the gas generator by the first set ofconduits, and wherein the exhaust fluid of the gas generator is sent tothe heat exchanger via the first set of conduits, and wherein the heatexchanger comprises a third set of conduits; and in response to adetermination that the temperature of the exhaust fluid satisfies thethreshold, increasing a water flow through the third set of conduits.24. The method of any of embodiments 20 to 23, further comprising:obtaining a harmonics measurement of the gas generator; determiningwhether the harmonics measurement satisfies a threshold; and in responseto a determination that the harmonics measurement satisfies thethreshold, actuating a valve attached to the generator inlet to reduce agas flow through the generator inlet.25. The method of any of embodiments 20 to 24, wherein the generatorinlet is a first generator inlet, and wherein the gas generatorcomprises a second generator inlet to receive fluid from atmosphericair, the method further comprising: determining whether the fluidmeasurement obtained by the sensor satisfies a threshold; and inresponse to a determination that the fluid measurement obtained by thesensor satisfies the threshold, actuate a valve to increase a flow of aninert gas from a gas source to a gas generator, wherein the valve isattached to a first conduit and a second conduit, wherein the firstconduit is connected to the second generator inlet, and wherein the gassource is attached to the second conduit.26. The method of any of embodiments 20 to 25, wherein the sensor is afirst sensor, the method further comprising: obtaining a measurement ofa height of a liquid in a first fluid tank based on a second sensor,wherein the second sensor is attached to the first fluid tank, andwherein fluid from the compressor is pumped to the first fluid tank;determining whether a measurement of the height of the liquid satisfiesa threshold; and in response to a determination that the measurement ofthe height satisfies the threshold, actuating a valve attached to afluid outlet of a second fluid tank, wherein: the fluid outlet is lowerin height than a first attachment point; a first conduit of the secondset of conduits is attached to the first fluid tank at the firstattachment point of the first fluid tank; the second fluid tank isconnected to the first fluid tank via the first conduit; the firstconduit is attached to the second fluid tank via a second attachmentpoint of the second fluid tank; the second attachment point is greaterin height relative to the first attachment point; and the second fluidtank is connected to the generator inlet via a third conduit of thesecond set of conduits.27. The method of any of embodiments 20 to 26, wherein the sensor is afirst sensor, the method further comprising: obtaining a nitrogen oxidemeasurement from a second sensor, wherein the second sensor measures theexhaust fluid; determining whether the nitrogen oxide measurementsatisfies an adjustment criterion; and in response to a determinationthat the nitrogen oxide measurement satisfies the adjustment criterion,actuating a valve to reduce a flow rate of atmospheric air that isflowing into the gas generator.28. The method of any of embodiments 20 to 27, further comprising:determining whether a temperature measurement of a temperature sensorsatisfies a threshold, wherein the temperature sensor measures theexhaust fluid; and in response to a determination that the temperaturemeasurement satisfies the threshold, actuating a valve to reduce theflow rate of the fluid mixture flowing into the gas generator.29. The method of any of embodiments 20 to 28, wherein the exhaust fluidgenerated by the gas generator is sent to a gas pressurizer via a thirdset of conduits, the method further comprising: increasing a pressure ofthe exhaust fluid in the gas pressurizer to generate liquid carbondioxide; and reducing a pressure of the liquid carbon dioxide in the gaspressurizer to generate solid carbon dioxide.30. The method of any of embodiments 29, further comprising: determininga sulfide content of the exhaust fluid; determining whether the sulfidecontent of the exhaust fluid satisfies a threshold; and in response to adetermination that the sulfide content of the exhaust fluid satisfiesthe threshold, reducing an amount of exhaust fluid provided to the gaspressurizer.31. The method of any of embodiments 20 to 30, further comprising:determining whether a pressure difference between a pressure of a fluidflowing through the generator outlet satisfies a threshold; and inresponse to a determination that the pressure difference satisfies thethreshold, actuating a valve to send the exhaust fluid flowing throughthe first set of conduits to the atmosphere, wherein the valve controlsa flow rate of the exhaust fluid to the atmosphere.32. The method of any of embodiments 20 to 31, wherein the sensor is afirst sensor, the method further comprising: determining that a fluidproperty measured by a second sensor of an evaporator satisfies athreshold, wherein the evaporator is connected to the generator outletvia a subset of conduits of the first set of conduits; and in responseto a determination that the fluid property satisfies the threshold,increasing a water flow through a third set of conduits by actuating anexhaust bypass valve, wherein the water flowing through the third set ofconduits is at a lesser temperature than the exhaust fluid flowing intothe evaporator, wherein the exhaust bypass valve controls an amount ofwater send to the evaporator.33. The method of any of embodiments 20 to 32, further comprising:determining whether a hydrocarbon concentration measurement of fluidflowing through the generator outlet satisfies a threshold; and inresponse to a determination that the hydrocarbon concentrationmeasurement satisfies the threshold, actuating a valve to increase anamount of oxygen flowing from a gas source, wherein the gas source isconnected to the generator inlet via the valve.34. The method of any of embodiments 20 to 33, further comprising:obtaining a target power output; obtaining a set of electricalmeasurements for a set of components electrically connected to the gasgenerator, wherein the set of electrical measurements comprises acurrent measurement or a voltage measurement; wherein obtaining thefluid measurement comprises obtaining a sequence of pressuremeasurements using the sensor; determining a set of predicted fluid flowrates based on the sequence of pressure measurements; determining asequence of predicted power outputs based on the set of predicted fluidflow rates; determining whether a predicted power output of the sequenceof predicted power outputs satisfies a criterion of the target poweroutput; and actuating a valve attached to a fluid tank in response to adetermination that the predicted power output does not satisfy thecriterion based on the target power output, wherein the fluid tank isconnected to the generator inlet.35. The method of any of embodiments 20 to 34, wherein the operationalparameter is a first parameter, and wherein the sensor is a firstsensor, the method further comprising: obtaining a target gasconsumption amount; wherein obtaining the fluid measurement comprisesobtaining a sequence of pressure measurements using a second sensorattached to the gas emission source; determining a set of predictedfluid flow rates based on the sequence of pressure measurements;determining a second parameter based on the set of predicted fluid flowrates and the target gas consumption amount; and configuring the set offluid control devices based on the second parameter.36. The method of any of embodiments 35, further comprising: determiningthat the set of predicted fluid flow rates indicate an increase in theamount of gas to be received from the gas emission source; increasing anallowable storage pressure of a fluid tank connected to the gasgenerator by a third set of conduits based on the increase in the amountof gas to be received from the gas emission source.37. An apparatus comprising: a gas generator to generate electricalenergy using a fluid mixture obtained via a generator inlet of the gasgenerator, wherein a portion of the fluid mixture comprises gas providedby a gas emission source; a compressor, wherein a compressor inlet ofthe compressor is attached to a generator outlet of the gas generator bya first set of conduits, and wherein exhaust fluid of the gas generatoris provided to the compressor via the first set of conduits, and whereinthe first set of conduits comprises a conduit attached to the gasemission source; a second set of conduits connecting a compressor outletof the compressor to the generator inlet; a sensor attached to thesecond set of conduits, wherein the sensor measures fluid properties offluids flowing through a portion of the second set of conduits.38. The apparatus of any of embodiments 37, wherein the set of fluidcontrol devices comprises at least one of the compressor or a valveattached to the first set of conduits, and wherein the gas emissionsource includes at least one of a hydrocarbon well, a landfill, or ananaerobic digester.39. The apparatus of any of embodiments 37 to 38, further comprising: aheat exchanger, wherein the heat exchanger is connected to the gasgenerator by the first set of conduits, and wherein the exhaust fluid ofthe gas generator is sent to the heat exchanger via the first set ofconduits, and wherein the heat exchanger comprises a third set ofconduits.40. The apparatus of any of embodiments 37 to 39, further comprising avalve attached to the generator inlet.41. The apparatus of any of embodiments 37 to 40, wherein the generatorinlet is a first generator inlet, and wherein the gas generatorcomprises a second generator inlet to receive fluid from atmosphericair, the apparatus further comprising: a first conduit connected to thesecond generator inlet; a valve attached to the first conduit, whereinthe valve is attached a second conduit; a gas source, wherein the gassource is attached to the second conduit.42. The apparatus of any of embodiments 37 to 41, further comprising: afirst fluid tank, wherein fluid from the compressor is pumped to thefirst fluid tank; a first conduit of the second set of conduits, whereinthe first conduit is attached to the first fluid tank at a firstattachment point of the first fluid tank; and a second fluid tankconnected to the first fluid tank via the first conduit, wherein: thefirst conduit is attached to the second fluid tank via a secondattachment point of the second fluid tank; the second attachment pointis greater in height relative to the first attachment point; and thesecond fluid tank is connected to the generator inlet via a thirdconduit of the second set of conduits.43. The apparatus of any of embodiments 42, wherein the sensor is afirst sensor, the apparatus further comprising: a second sensor attachedto the first fluid tank; and a valve attached to a fluid outlet of thesecond fluid tank, wherein the fluid outlet is lower in height than thefirst attachment point.44. The apparatus of any of embodiments 37 to 43, wherein the sensor isa first sensor, the apparatus further comprising: a nitrogen oxidesensor to measure the exhaust fluid; and a valve to reduce a flow rateof atmospheric air that is flowing into the gas generator.45. The apparatus of any of embodiments 37 to 44, the apparatus furthercomprising: a temperature sensor to measure the exhaust fluid; and avalve to reduce the flow rate of the fluid mixture flowing into the gasgenerator.46. The apparatus of any of embodiments 37 to 45, further comprising avalve of a second conduit of the gas generator controlling an amount ofexhaust fluid flowing into the generator inlet.47. The apparatus of any of embodiments 37 to 46, further comprising: agas pressurizer, wherein the exhaust fluid generated by the gasgenerator is sent to the gas pressurizer via a third set of conduits.48. The apparatus of any of embodiments 47, further comprising a sulfidecontent sensor to measure the exhaust fluid.49. The apparatus of any of embodiments 37 to 48, further comprising avalve that controls a flow rate of the exhaust fluid to the atmosphere.50. The apparatus of any of embodiments 37 to 49, wherein the sensor isa first sensor, the apparatus further comprising: an evaporator that isconnected to the generator outlet via a subset of conduits of the firstset of conduits; an exhaust bypass valve, wherein the exhaust bypassvalve controls an amount of water send to the evaporator; a third set ofconduits attached to the exhaust bypass valve, wherein water flowingthrough the third set of conduits is at a lesser temperature than theexhaust fluid flowing into the evaporator.51. The apparatus of any of embodiments 50, further comprising: a secondset of tanks, wherein the second set of tanks receives fluid from theevaporator; a filter to collect solids of the fluid in the second set oftanks; a third set of tanks, wherein the third set of tanks receivefiltered fluid from the second set of tanks; and a third conduitconnecting the third set of tanks to the evaporator.52. The apparatus of any of embodiments 37 to 51, further comprising agas source storing oxygen, wherein the gas source is connected to thegenerator inlet via a valve.53. The apparatus of any of embodiments 37 to 52, further comprising avalve attached to a fluid tank, wherein the fluid tank is connected tothe generator inlet.54. The apparatus of any of embodiments 53, further comprising a fluidtank connected to the gas generator by a third set of conduits.55. The system of any of embodiments 1 to 19, the operations furthercomprising: receiving a wireless signal via a network interface; anddetermining the target value based on the wireless signal.56. The system of any of embodiments 1 to 19, the operations furthercomprising filtering fluid from gas emission source to obtain solidmatter, wherein the solid matter comprises at least one of transitionmetals or alkali metals.57. The system of any of embodiments 1 to 19, the operations furthercomprising converting at least a portion of the exhaust gas into solidcarbon dioxide.

What is claimed is:
 1. A system comprising: a gas generator to generateelectrical energy using a fluid mixture obtained via a generator inletof the gas generator, wherein a portion of the fluid mixture comprisesgas provided by a gas emission source; a compressor, wherein acompressor inlet of the compressor is attached to a generator outlet ofthe gas generator by a first set of conduits, and wherein exhaust fluidof the gas generator is provided to the compressor via the first set ofconduits, and wherein the first set of conduits comprises a conduitattached to the gas emission source; a second set of conduits connectinga compressor outlet of the compressor to the generator inlet; a sensorin communication with the second set of conduits, wherein the sensormeasures fluid properties of fluids flowing through a portion of thesecond set of conduits; a non-transitory, machine-readable medium ofstoring instructions that, when executed by a computer system,effectuate operations comprising: obtaining, with the computer system, atarget fluid property of the fluid mixture entering the generator inlet;obtaining, with the computer system, a fluid measurement of the fluidmixture using the sensor; determining, with the computer system, whetherthe fluid measurement satisfies a criterion based on the target fluidproperty; and in response to a determination that the target fluidproperty satisfies the criterion, modifying, with the computer system,an operational parameter of a set of fluid control devices to increase afirst flow rate relative to a second flow rate, wherein the first flowrate is a measurement of the flow of the exhaust fluid through thesecond set of conduits, and wherein the second flow rate is ameasurement of the flow of the gas provided by the gas emission sourcethrough the first set of conduits.
 2. The system of claim 1, wherein theset of fluid control devices comprises at least one of the compressor ora valve attached to the first set of conduits, and wherein the gasemission source includes at least one of a hydrocarbon well, a landfill,or an anaerobic digester.
 3. The system of claim 1, further comprising:a heat exchanger, wherein the heat exchanger is connected to the gasgenerator by the first set of conduits, and wherein the exhaust fluid ofthe gas generator is sent to the heat exchanger via the first set ofconduits, and wherein the heat exchanger comprises a third set ofconduits, the operations further comprising: determining whether atemperature of the exhaust fluid flowing through an outlet of the heatexchanger satisfies a threshold; and in response to a determination thatthe temperature of the exhaust fluid satisfies the threshold, increasinga water flow through the third set of conduits.
 4. The system of claim1, the operations further comprising: obtaining a harmonics measurementof the gas generator; determining whether the harmonics measurementsatisfies a threshold; and in response to a determination that theharmonics measurement satisfies the threshold, actuating a valveattached to the generator inlet to reduce a gas flow through thegenerator inlet.
 5. The system of claim 1, wherein the generator inletis a first generator inlet, and wherein the gas generator comprises asecond generator inlet to receive fluid from atmospheric air, the systemfurther comprising: a first conduit connected to the second generatorinlet; a valve attached to the first conduit, wherein the valve isattached to a second conduit; a gas source, wherein the gas source isattached to the second conduit, the operations further comprising:determining whether the fluid measurement obtained by the sensorsatisfies a threshold; and in response to a determination that the fluidmeasurement obtained by the sensor satisfies the threshold, actuate thevalve to increase a flow of an inert gas from the gas source to the gasgenerator.
 6. The system of claim 1, further comprising: a first fluidtank, wherein fluid from the compressor is pumped to the first fluidtank; a first conduit of the second set of conduits, wherein the firstconduit is attached to the first fluid tank at a first attachment pointof the first fluid tank; and a second fluid tank connected to the firstfluid tank via the first conduit, wherein: the first conduit is attachedto the second fluid tank via a second attachment point of the secondfluid tank; the second attachment point is greater in height relative tothe first attachment point; and the second fluid tank is connected tothe generator inlet via a third conduit of the second set of conduits.7. The system of claim 6, wherein the sensor is a first sensor, thesystem further comprising a second sensor in communication with thefirst fluid tank, the operations further comprising: obtaining ameasurement of a height of a liquid in the first fluid tank based on thesecond sensor; determining whether the measurement of the height of theliquid satisfies a threshold; and in response to a determination thatthe measurement of the height satisfies the threshold, actuating a valveattached to a fluid outlet of the second fluid tank, wherein the fluidoutlet is lower in height than the first attachment point.
 8. The systemof claim 1, wherein the sensor is a first sensor, the operations furthercomprising: obtaining a nitrogen oxide measurement from a second sensor,wherein the second sensor measures the exhaust fluid; determiningwhether the nitrogen oxide measurement satisfies an adjustmentcriterion; and in response to a determination that the nitrogen oxidemeasurement satisfies the adjustment criterion, actuating a valve toreduce a flow rate of atmospheric air that is flowing into the gasgenerator.
 9. The system of claim 1, the system further comprising atemperature sensor to measure the exhaust fluid, the operations furthercomprising: determining whether a temperature measurement of thetemperature sensor satisfies a threshold; and in response to adetermination that the temperature measurement satisfies the threshold,actuating a valve to reduce the flow rate of the fluid mixture flowinginto the gas generator.
 10. The system of claim 1, the operationsfurther comprising: determining whether an energy density of a recycledfluid mixture flowing from the compressor satisfies a threshold; and inresponse to a determination that the energy density of the recycledfluid mixture satisfies the threshold, actuating a valve of a secondconduit of the gas generator to increase an amount of exhaust fluidflowing into the generator inlet.
 11. The system of claim 1, furthercomprising a gas pressurizer, wherein the exhaust fluid generated by thegas generator is sent to the gas pressurizer via a third set ofconduits, the operations further comprising: increasing a pressure ofthe exhaust fluid in the gas pressurizer to generate liquid carbondioxide; and reducing a pressure of the liquid carbon dioxide in the gaspressurizer to generate solid carbon dioxide.
 12. The system of claim11, the operations further comprising: determining a sulfide content ofthe exhaust fluid; determining whether the sulfide content of theexhaust fluid satisfies a threshold; and in response to a determinationthat the sulfide content of the exhaust fluid satisfies the threshold,reducing an amount of exhaust fluid provided to the gas pressurizer. 13.The system of claim 1, the system further comprising a valve, wherein:the valve controls a flow rate of the exhaust fluid to the atmosphere;and the operations further comprise: determining whether a pressuredifference between a pressure of a fluid flowing through the generatoroutlet satisfies a threshold; and in response to a determination thatthe pressure difference satisfies the threshold, actuating the valve tosend the exhaust fluid flowing through the first set of conduits to theatmosphere.
 14. The system of claim 1, wherein the sensor is a firstsensor, the system further comprising: an evaporator that is connectedto the generator outlet via a subset of conduits of the first set ofconduits; an exhaust bypass valve, wherein the exhaust bypass valvecontrols an amount of water send to the evaporator, the operationsfurther comprising: determining that a fluid property measured by asecond sensor of the evaporator satisfies a threshold; and in responseto a determination that the fluid property satisfies the threshold,increasing a water flow through a third set of conduits by actuating theexhaust bypass valve, wherein the water flowing through the third set ofconduits is at a lesser temperature than the exhaust fluid flowing intothe evaporator.
 15. The system of claim 14, further comprising: a secondset of tanks, wherein the second set of tanks receives fluid from theevaporator; a filter to collect solids of the fluid in the second set oftanks; a third set of tanks, wherein the third set of tanks receivefiltered fluid from the second set of tanks; and a third conduitconnecting the third set of tanks to the evaporator.
 16. The system ofclaim 1, further comprising a gas source, wherein: the gas source isconnected to the generator inlet via a valve; and the operations furthercomprise: determining whether a hydrocarbon concentration measurement offluid flowing through the generator outlet satisfies a threshold; and inresponse to a determination that the hydrocarbon concentrationmeasurement satisfies the threshold, actuating the valve to increase anamount of oxygen flowing from the gas source.
 17. The system of claim 1,the operations further comprising: obtaining a target power output;obtaining a set of electrical measurements for a set of componentselectrically connected to the gas generator, wherein the set ofelectrical measurements comprises a current measurement or a voltagemeasurement; wherein obtaining the fluid measurement comprises obtaininga sequence of pressure measurements using the sensor; determining a setof predicted fluid flow rates based on the sequence of pressuremeasurements; determining a sequence of predicted power outputs based onthe set of predicted fluid flow rates; determining whether a predictedpower output of the sequence of predicted power outputs satisfies acriterion of the target power output; and actuating a valve attached toa fluid tank in response to a determination that the predicted poweroutput does not satisfy the criterion based on the target power output,wherein the fluid tank is connected to the generator inlet.
 18. Thesystem of claim 1, wherein the operational parameter is a firstparameter, and wherein the sensor is a first sensor, the operationsfurther comprising: obtaining a target gas consumption amount; whereinobtaining the fluid measurement comprises obtaining a sequence ofpressure measurements using a second sensor in communication with thegas emission source; determining a set of predicted fluid flow ratesbased on the sequence of pressure measurements; determining a secondparameter based on the set of predicted fluid flow rates and the targetgas consumption amount; and configuring the set of fluid control devicesbased on the second parameter.
 19. The system of claim 18, theoperations further comprising: determining that the set of predictedfluid flow rates indicate an increase in the amount of gas to bereceived from the gas emission source; increasing an allowable storagepressure of a fluid tank connected to the gas generator by a third setof conduits based on the increase in the amount of gas to be receivedfrom the gas emission source.
 20. A method comprising: obtaining, with acomputer system, a target fluid property of a fluid mixture entering agenerator inlet of a gas generator, wherein: the gas generator generateselectrical energy using the fluid mixture obtained via the generatorinlet, a portion of the fluid mixture comprises gas provided by a gasemission source, a compressor inlet of a compressor is attached to agenerator outlet of the gas generator by a first set of conduits,exhaust fluid of the gas generator is provided to the compressor via thefirst set of conduits; a second set of conduits connects a compressoroutlet of the compressor to the generator inlet; and a sensor measuresfluid properties of fluids flowing through a portion of the second setof conduits; obtaining, with the computer system, a fluid measurement ofthe fluid mixture using the sensor; determining, with the computersystem, whether the fluid measurement satisfies a criterion based on thetarget fluid property; and in response to a determination that thetarget fluid property satisfies the criterion, modifying, with thecomputer system, an operational parameter of a set of fluid controldevices to increase a first flow rate relative to a second flow rate,wherein the first flow rate is a measurement of the flow of the exhaustfluid through the first set of conduits, and wherein the second flowrate is a measurement of the flow of the gas provided by the gasemission source through the first set of conduits.